Splice variants associated with neomorphic SF3B1 mutants

ABSTRACT

Splice variants associated with neomorphic SF3B1 mutations are described herein. This application also relates to methods of detecting the described splice variants, and uses for diagnosing cancer, evaluating modulators of SF3B1, and methods of treating cancer associated with mutations in SF3B1.

The present application is a continuation of U.S. patent application Ser. No. 15/755,225, filed Feb. 26, 2018, which is a national stage application under 35 U.S.C. § 371 of international application number PCT/US2016/049490, filed Aug. 30, 2016, which designated the U.S. and claims the benefit of priority to U.S. Provisional Patent Application No. 62/212,876, filed Sep. 1, 2015, the contents of which are hereby incorporated by reference herein in their entirety.

The instant application contains a Sequence Listing which has been submitted electronically in ASCII format and is hereby incorporated by reference in its entirety. The ASCII copy, created on May 16, 2014, is named 12636.6-304_ SL.txt and is 183 kilobytes in size.

RNA splicing, a highly regulated molecular event orchestrated by the spliceosome, results in the removal of intronic sequences from pre-mRNA to generate mature mRNA. Dysregulation of RNA splicing has been identified as a causative defect in several diseases. In addition, dysregulated splicing has been proposed to play an important role in tumorigenesis and resistance to therapy; however, the molecular causes of dysregulated splicing in cancer have remained elusive.

SF3B1 is a protein involved in RNA splicing. It forms part of the U2 snRNP complex which binds to the pre-mRNA at a region containing the branchpoint site and is involved in early recognition and stabilization of the spliceosome at the 3′ splice site (3′ss). A thorough and systematic analysis of the effects of SF3B1 mutations is needed to define their effects on RNA splicing in cells and may lead to novel therapeutic approaches for SF3B1 mutant cancers.

The description provided herein demonstrates that certain SF3B1 mutations result in neomorphic activity with the production of known and novel splicing alterations. In addition, lineage-specific splicing aberrations were identified in chronic lymphocytic leukemia (CLL), melanoma, and breast cancer. Furthermore, treatment of SF3B1-mutant cancer cell lines, xenografts, and CLL patient samples with modulators of SF3B1 reduced aberrant splicing and induced tumor regression.

SUMMARY

The methods described herein involve detecting or quantifying the expression of one or more splice variants in a cell containing a neomorphic mutant SF3B1 protein. Various embodiments of the invention include detecting or quantifying splice variants to determine whether a patient has a cancer with one or more neomorphic SF3B1 mutations. Additional embodiments include measuring the amount of a splice variant to evaluate the effects of a compound on a mutant SF3B1 protein. Further embodiments include methods of treating a patient who has cancer cells with a neomorphic mutant SF3B1 protein.

Various embodiments encompass a method of detecting one or more splice variants selected from rows 1-790 of Table 1 in a biological sample, comprising:

a) providing a biological sample suspected of containing one or more splice variants;

b) contacting the biological sample with one or more nucleic acid probes capable of specifically hybridizing to the one or more splice variants, and

c) detecting the binding of the one or more probes to the one or more splice variants.

In some embodiments, the one or more nucleic acid probes capable of specifically hybridizing to the one or more splice variants each comprise a label. In some embodiments, the method of detecting one or more splice variants selected from rows 1-790 of Table 1 in a biological sample further comprises contacting the biological sample with one or more additional nucleic acid probes, wherein the additional probes are each labeled with a molecular barcode.

Embodiments further encompass a method of modulating the activity of a neomorphic mutant SF3B1 protein in a target cell, comprising applying an SF3B1-modulating compound to the target cell, wherein the target cell has been determined to express one or more aberrant splice variants selected from rows 1-790 of Table 1 at a level that is increased or decreased relative to the level in a cell not having the neomorphic mutant SF3B1 protein.

Embodiments also encompass a method for evaluating the ability of a compound to modulate the activity of a neomorphic mutant SF3B1 protein in a target cell, comprising the steps of:

a) providing a target cell having a mutant SF3B1 protein;

b) applying the compound to the target cell; and

c) measuring the expression level of one or more splice variants selected from row 1-790 of Table 1.

In some embodiments, the method for evaluating the ability of a compound to modulate the activity of a neomorphic mutant SF3B1 protein in a target cell further comprises the step of measuring the expression level of one or more splice variants selected from row 1-790 of Table 1 before step (b).

In some embodiments, the neomorphic mutant SF3B1 protein is selected from K700E, K666N, R625C, G742D, R625H, E622D, H662Q, K666T, K666E, K666R, G740E, Y623C, T663I, K741N, N626Y, T663P, H662R, G740V, D781E, or R625L. In some embodiments, the neomorphic mutant SF3B1 protein is selected from E622D, E622K, E622Q, E622V, Y623C, Y623H, Y623S, R625C, R625G, R625H, R625L, R625P, R625S, N626D, N626H, N626I, N626S, N626Y, H662D, H662L, H662Q, H662R, H662Y, T663I, T663P, K666E, K666M, K666N, K666Q, K666R, K666S, K666T, K700E, V701A, V701F, V701I, I704F, I704N, I704S, I704V, G740E, G740K, G740R, G740V, K741N, K741Q, K741T, G742D, D781E, D781G, or D781N.

In some embodiments, the step of measuring the expression level of one or more splice variants comprises using an assay to quantify nucleic acid selected from nucleic acid barcoding (e.g. NanoString®), RT-PCR, microarray, nucleic acid sequencing, nanoparticle probes (e.g. SmartFlare™), and in situ hybridization (e.g. RNAscope®).

In some embodiments, the step of measuring the expression level of one or more splice variants comprises measuring the number of copies of the one or more splice variant RNAs in the target cell.

In further embodiments, the compound is selected from a small molecule, an antibody, an antisense molecule, an aptamer, an RNA molecule, and a peptide. In further embodiments, the small molecule is selected from pladienolide and a pladienolide analog. In additional embodiments, the pladienolide analog is selected from pladienolide B, pladienolide D, E7107, a compound of formula 1:

a compound of formula 2:

a compound of formula 3:

or a compound of formula 4:

In some embodiments, the target cell is obtained from a patient suspected of having myelodysplastic syndrome, chronic lymphocytic leukemia, chronic myelomonocytic leukemia, or acute myeloid leukemia. In some embodiments, the target cell is obtained from a sample selected from blood or a blood fraction or is a cultured cell derived from a cell obtained from a sample chosen from blood or a blood fraction. In some embodiments, the target cell is a lymphocyte.

In further embodiments, the target cell is obtained from a solid tumor. In some embodiments, the target cell is a breast tissue cell, pancreatic cell, lung cell, or skin cell.

In some embodiments, one or more of the aberrant variants are selected from rows 1, 7, 9, 10, 13, 15, 16, 18, 21, 24, 27, 28, 30, 31, 33, 34, 48, 51, 62, 65, 66, 71, 72, 81, 84, 89, 91, 105, 107, 121, 135, 136, 152, 178, 235, 240, 247, 265, 267, 272, 276, 279, 282, 283, 286, 292, 295, 296, 298, 302, 306, 329, 330, 331, 343, 350, 355, 356, 360, 364, 372, 378, 390, 391, 423, 424, 425, 426, 431, 433, 438, 439, 443, 445, 447, 448, 451, 452, 458, 459, 460, 462, 468, 469, 472, 500, 508, 517, 519, 521, 524, 525, 527, 528, 530, 533, 536, 540, 543, 548, 545, 554, 556, 559, 571, 573, 580, 582, 583, 597, 601, 615, 617, 618, 639, 640, 654, 657, 666, 670, 680, 727, 730, 750, 758, 767, or 774 of Table 1.

In some embodiments, one or more of the aberrant variants are selected from rows 21, 31, 51, 81, 118, 279, 372, 401, 426, 443, 528, 543, 545, 548 or 566 of Table 1.

Embodiments further encompass a method for treating a patient with a neoplastic disorder, comprising administering a therapeutically effective amount of an SF3B1-modulating compound to the patient, wherein a cell from the patient has been determined to:

a) contain a neomorphic mutant SF3B1 protein; and

b) express one or more aberrant splice variants selected from rows 1-790 of Table 1 at a level that is increased or decreased relative to the level in a cell not having the neomorphic mutant SF3B1 protein.

Additional embodiments are set forth in the description which follows.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention, as claimed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram depicting modes of alternative splicing.

FIG. 2 is a graph depicting levels of gene expression for abnormally spliced genes across different cancers in patient samples.

FIG. 3 is a schematic diagram showing the locations of certain neomorphic mutations in the SF3B1 protein and corresponding coding regions of the SF3B1 gene.

FIG. 4 is a graph depicting levels of aberrant splice variants detected in RNA isolated from pancreatic, lung cancer, and Nalm-6 isogenic cell lines using a NanoString® assay. Data are represented as the mean of three replicates.

FIG. 5 is a set of western blot images that confirm overexpression of SF3B1 proteins in 293FT cells.

FIG. 6 is a graph depicting levels of aberrant splice variants in RNA isolated from 293FT cells expressing wild type SF3B1 (SF3B1^(WT)) or mutant SF3B1 proteins, as measured in a NanoString® assay. Data are represented as the mean of three replicates.

FIG. 7 is a set of western blot images that confirm overexpression of SF3B1 proteins in 293FT cells.

FIG. 8 is a graph depicting levels of aberrant splice variants in RNA isolated from 293FT cells expressing SF3B1^(WT) or mutant SF3B1 proteins, as measured in a NanoString® assay.

FIG. 9A depicts a set of western blot images showing expression of SF3B1 alleles before and after shRNA-knockdown in Panc 05.04 cells. FIG. 9B depicts a graph showing levels of SF3B1 RNA detected by qPCR in Panc 05.04 cells before and after shRNA-knockdown of all SF3B1 alleles (“SF3B1^(PAN)) or SF3B1^(WT) or mutant SF3B1 (SF3B1^(MUT)) alleles. qPCR data are represented as fold change relative to pLKO non-treated with doxycycline (mean±SD, n=3). Solid black, outlined, and gray bars indicate SF3B1^(PAN), SF3B1^(WT), and SF3B1^(MUT) allele-specific qPCR data, respectively.

FIG. 10A depicts a set of western blot images showing expression of SF3B1 alleles before and after shRNA-knockdown in Panc 10.05 cells. FIG. 10B depicts a graph showing levels of SF3B1 RNA detected by qPCR in Panc 10.05 cells before and after shRNA-knockdown of SF3B1 alleles. qPCR data are represented as fold change relative to pLKO non-treated with doxycycline (mean±SD, n=3). Solid black, outlined, and gray bars indicate SF3B1^(PAN), SF3B1^(WT), and SF3B1^(MUT) allele-specific qPCR data, respectively.

FIGS. 11A and 11B are a set of graphs depicting levels of splice variants in Panc 05.04 (FIG. 11A) and Panc 10.05 cells (FIG. 11B) before and after shRNA-knockdown of SF3B1 alleles, as measured in a NanoString® assay. Data are represented as mean of three biological replicates.

FIG. 12 is a set of graphs depicting growth curves of Panc 05.04 cells before (circles) and after (squares) shRNA-knockdown of SF3B1 alleles.

FIG. 13 is a set of graphs depicting growth curves of Panc 10.05 cells before (circles) and after (squares) shRNA-knockdown of SF3B1 alleles.

FIGS. 14A and 14B are a set of images of culture plates showing colony formation of Panc 05.04 cells (FIG. 14A) and Panc 10.05 (FIG. 14B) cells before and after shRNA-knockdown of SF3B1 alleles.

FIGS. 15A and 15B are a set of graphs showing the level of splicing of pre-mRNA Ad2 substrate in nuclear extracts from (FIG. 15A) 293F cells expressing Flag-tag SF3B1^(WT) or SF3B1^(K700E) (left and right panels [circles and triangles], respectively) and (FIG. 15B) Nalm-6 (SF3B1^(WT)) and Nalm-6 SF3B1^(K700E) cells (left and right panels [circles and triangles], respectively) treated with varying concentrations of E7101. Data are represented as mean±SD, n=2.

FIG. 16A depicts a pair of graphs showing the binding of a radiolabeled E7107 analog to either SF3B1^(WT) (circles, left panel) or SF3B1^(K700E) (triangles, right panel) after incubation of the proteins with varying concentrations of E7107. FIG. 16B depicts upper panels, a pair of graphs showing the levels of EIF4A1 pre-mRNA (squares) and SLC25A19 mature RNA (inverted triangles) in Nalm-6 SF3B1^(K700K) cells (left panel) and Nalm-6 SF3B1^(K700E) cells (right panel) treated with varying concentrations of E7107, as measured by qPCR. FIG. 16B depicts lower panels, a pair of graphs showing the levels of abnormally spliced isoforms of abnormally spliced genes COASY (triangles) and ZDHHC16 (diamonds) in Nalm-6 SF3B1^(K700K) cells (left panel) and Nalm-6 SF3B1^(K700E) cells (right panel) treated with varying concentrations of E7107, as measured by qPCR. qPCR data in (FIG. 16B) are represented as mean±SD (n=3).

FIG. 17 is a set of graphs depicting levels of splice variants in Nalm-6 SF3B1^(K700K) and Nalm-6 SF3B1^(K700E) cells after treatment of cells with E7107 for two or six hours, as measured in a NanoString® assay. Data are expressed as fold change from DMSO-only treatment

FIG. 18 is a set of graphs depicting levels of splice variants in Nalm-6 SF3B1^(K700K) and Nalm-6 SF3B1^(K700E) cells after treatment of cells with E7107 for six hours, as measured by RNA-Seq analysis.

FIG. 19 is a set of graphs depicting levels of splice variants in Nalm-6 SF3B1^(K700K) and Nalm-6 SF3B1^(K700E) cells after treatment of cells with the numbered compounds indicated above the graphs, as measured by RNA-Seq analysis.

FIG. 20 is set of graphs depicting levels of splice variants in Nalm-6 SF3B1^(K700K) and Nalm-6 SF3B1^(K700E) cells at varying times following treatment of cells with E7107, as measured by qPCR of RNA. Data are represented as mean±SD (n=3). The upper panels of FIG. 20 depict the levels of EIF4A1 pre-mRNA (squares) and SLC25A19 mature RNA (inverted triangles) in Nalm-6 SF3B1^(K700K) cells (left panel) and Nalm-6 SF3B1^(K700E) cells (right panel) detected at certain times after treatment with E7107. The lower panels of FIG. 20 depict the levels of abnormally spliced isoforms of abnormally spliced genes COASY (triangles) and ZDHHC16 (diamonds) in Nalm-6 SF3B1^(K700K) cells (left panel) and Nalm-6 SF3B1^(K700E) cells (right panel) detected at certain times after treatment with E7107. Open circles show the concentration of E7107 (in μg/ml [right vertical axis]) as determined by mass spectrometry of tumor samples.

FIG. 21 is a set of graphs depicting levels of canonical and aberrant splice variants in Nalm-6 SF3B1^(K700K)- and Nalm-6 SF3B1^(K700E)-xenograft tumors (left and right sets of panels, respectively) at certain timepoints after treatment of xenograft mice with E7107, as measured in a NanoString® assay. Data are represented as mean of three replicates.

FIG. 22 is a set of graphs depicting levels of canonical and aberrant splice variants in Panc 05.04-xenograft tumors at certain timepoints after treatment of xenograft mice with E7107 at various concentrations, as measured in a NanoString® assay (n=4 mice for each group).

FIG. 23 is a graph depicting tumor volume (shown as mean±SEM) in Nalm-6 SF3B1^(K700E)-xenograft mice following treatment with E7107, with control mice treated with vehicle shown by open circles (n=10 animals for each group). For E7107-treated animals, inverted triangles=1.25 mg/kg, triangles=2.5 mg/kg, and squares=5 mg/kg.

FIG. 24 is a graph depicting survival rates in 10-animal cohorts of Nalm-6 SF3B1^(K700E)-xenograft mice following treatment with E7107, with an untreated cohort shown by the solid black line. For E7107-treated animals, dashed line=1.25 mg/kg, gray line=2.5 mg/kg, and dotted line=5 mg/kg.

FIG. 25 is set of graphs depicting levels of splice variants in SF3B1^(WT) and neomorphic SF3B1 mutant CLL cell samples following treatment with 10 nM E7107 for 6 hours, as measured by analysis. Data are represented as mean values (n=3).

DESCRIPTION OF THE EMBODIMENTS

In certain aspects, the methods of the invention provide assays for measuring the amount of a splice variant in a cell, thereby determining whether a patient has a cancer with a neomorphic SF3B1 mutation. In some embodiments, at least one of the measured splice variants is an aberrant splice variant associated with a neomorphic mutation in an SF3B1 protein. In additional aspects, the measurement of a splice variant in a cell may be used to evaluate the ability of a compound to modulate a mutant neomorphic SF3B1 protein in a cell.

To assist in understanding the present invention, certain terms are first defined. Additional definitions are provided throughout the application.

As used herein, the term “mutant SF3B1 protein” includes SF3B1 proteins that differ in amino acid sequence from the human wild type SF3B1 protein set forth in SEQ ID NO:1200 (GenBank Accession Number NP_036565, Version NP_036565.2) (S. Bonnal, L. Vigevani, and J. Valcárcel, “The spliceosome as a target of novel antitumour drugs,” Nat. Rev. Drug Discov. 11:847-59 [2012]). Certain mutant SF3B1 proteins are “neomorphic” mutants, which refers to mutant SF3B1 proteins that are associated with differential expression of aberrant splice variants. In certain embodiments, neomorphic SF3B1 mutants include K700E, K666N, R625C, G742D, R625H, E622D, H662Q, K666T, K666E, K666R, G740E, Y623C, T663I, K741N, N626Y, T663P, H662R, G740V, D781E, or R625L. In other embodiments, neomophic SF3B1 mutants include E622D, E622K, E622Q, E622V, Y623C, Y623H, Y623S, R625C, R625G, R625H, R625L, R625P, R625S, N626D, N626H, N626I, N626S, N626Y, H662D, H662L, H662Q, H662R, H662Y, T663I, T663P, K666E, K666M, K666N, K666Q, K666R, K666S, K666T, K700E, V701A, V701F, V701I, I704F, I704N, I704S, I704V, G740E, G740K, G740R, G740V, K741N, K741Q, K741T, G742D, D781E, D781G, or D781N. Certain SF3B1 mutations are not associated with expression of aberrant splice variants, including K700R.

The term “splice variant” as used herein includes nucleic acid sequences that span a junction either between two exon sequences or across an intron-exon boundary in a gene, where the junction can be alternatively spliced. Alternative splicing includes alternate 3′ splice site selection (“3′ss”), alternate 5′ splice site selection (“5′ss”), differential exon inclusion, exon skipping, and intron retention (FIG. 1 ). Certain splice variants associated with a given genomic location may be referred to as wild type, or “canonical,” variants. These splice variants are most abundantly expressed in cells that do not contain a neomorphic SF3B1 mutant protein. Additional splice variants may be referred to as “aberrant” splice variants, which differ from the canonical splice variant and are primarily associated with the presence of a neomorphic SF3B1 mutant protein in a cell. Aberrant splice variants may alternatively be referred to as “abnormal” or “noncanonical” splice variants. In certain circumstances, cells with a wild type or non-neomorphic SF3B1 protein have low or undetected amounts of an aberrant splice variant, while cells with a neomorphic SF3B1 protein have levels of an aberrant splice variant that are elevated relative to the low or undetected levels in the wild type SF3B1 cells. In some cases, an aberrant splice variant is a splice variant that is present in a wild type SF3B1 cell but is differentially expressed in a cell that has a neomorphic SF3B1 mutant, whereby the latter cell has a level of the aberrant splice variant that is elevated or reduced relative to the level in the wild type SF3B1 cell. Different types of cells containing a neomorphic SF3B1 mutant, such as different types of cancer cells, may have differing levels of expression of certain aberrant splice variants. In addition, certain aberrant splice variants present in one type of cell containing a neomorphic SF3B1 mutant may not be present in other types of cells containing a neomorphic SF3B1 mutant. In some cases, patients with a neomorphic SF3B1 mutant protein may not express an aberrant splice variant or may express an aberrant splice variant at lower levels, due to low allelic frequency of the neomorphic SF3B1 allele. The identity and relative expression levels of aberrant splice variants associated with various types of cells containing neomorphic SF3B1 mutants, such as certain cancer cells, will be apparent from the description and examples provided herein.

The term “evaluating” includes determining the ability of a compound to treat a disease associated with a neomorphic SF3B1 mutation. In some instances, “evaluating” includes determining whether or to what degree a compound modulates aberrant splicing events associated with a neomorphic SF3B1 protein. Modulation of the activity of an SF3B1 protein may encompass up-regulation or down-regulation of aberrant splice variant expression associated with a neomorphic SF3B1 protein. Additionally, “evaluating” includes distinguishing patients that may be successfully treated with a compound that modulates the expression of splice variants associated with a neomorphic SF3B1 protein.

The use of the word “a”, “an” or “the” when used in conjunction with the term “comprising” in the claims or the specification may mean “one,” but it is also consistent with the meaning of “one or more,” “at least one,” and “one or more than one.” “Or” is to be read inclusively to mean “and/or” unless explicitly indicated to refer to alternatives only, such as where alternatives are mutually exclusive.

Splice Variants

Splice variants of the invention are listed in Table 1. Table 1 provides the genomic location of each canonical (“WT”) and aberrant (“Ab.”) splice junction, as well as the sequence. Each sequence listed in the table contains 20 nucleotides from each of the 3′ and 5′ sides of a splice junction (i.e., the splice junction is at the midpoint of the listed nucleotide sequence). The “Avg WT %” and “Avg Ab. %” columns provide the average percentage count that the canonical (WT) or aberrant splice variant, respectively, represented out of the total counts of all splice variants that utilize a shared splice site, where the counts were determined as set forth in Example 1. The “Log₂ Fold Change” column provides the log₂ of the fold change observed between percentage counts of canonical and aberrant cohorts (see Example 1). The “FDR Q-Value” column provides, as a measure of statistical significance, q-values calculated using the Benjamin-Hochberg procedure from p-values, which in turn were determined using the moderated t-test defined in the Bioconductor's limma package (see Example 1). The “Event” column indicates the nature of the aberrant splice variant, where “3′ss” indicates alternate 3′ splice site selection, “5′ss” indicates alternate 5′ splice site selection, “exon incl.” indicates differential exon inclusion, and “exon skip” indicates exon skipping. The “Type” column refers to the cancer type of the sample in which the aberrant splice variant was identified, where “Br.” indicates breast cancer, “CLL” indicates chronic lymphocytic leukemia, and “Mel.” indicates melanoma.

TABLE 1 Aberrant WT Log₂ Aberrant sequence sequence Avg WT Avg Ab. Fold FDR Q- junction  WT junction (SEQ ID NO) (SEQ ID NO) % %  Diff. Value Event Type 1 chr2: chr2: AGCAAGTAGAAG AGCAAGTAGAAG 0 56 5.83 6.30E−07 3′ss Br. 109102364- 109102364- TCTATAAAATTT TCTATAAAATAC 109102954 109102966 ACCCCCAGATAC AGCTGGCTGAAA AGCT (1) TAAC (2) 2 chr16: chr16: CGGGCCGCATCA CGGGCCGCATCA 0 51 5.70 2.38E−07 3′ss Br. 708344- 708344- TCCGGGAGAGCA TCCGGGAGCTGC 708509 708524 CTGTGTTCCAGC CCGGTGTCCACC TGCC (3) CTGA (4) 3 chr3: chr3: CTGGAGCCGGCG CTGGAGCCGGCG 0 51 5.70 2.19E−07 3′ss Br. 50380021- 50380000- GGAAGGAGTGTG GGAAGGAGGCAA 50380348 50380348 CTGGTTCCTCTC GCTGCAGCAGTT CCCA (5) CGAG (6) 4 chr19: chr19: GGCCCTTTTGTC GGCCCTTTTGTC 0 48 5.61 2.32E−06 3′ss Br. 57908542- 57908542- CTCACTAGCATT CTCACTAGGTTC 57909780 57909797 TCTGTTCTGACA TTGGCATGGAGC GGTT (7) TGAG (8) 5 chr2: chr2: TGGGAGGAGCAT TGGGAGGAGCAT 0 47 5.58 7.79E−07 3′ss Br. 97285513- 97285499- GTCAACAGAGTT GTCAACAGGACT 97297048 97297048 TCCCTTATAGGA GGCTGGACAATG CTGG (9) GCCC (10) 6 chr19: chr19: GATGGTGGATGA GATGGTGGATGA 0 46 5.55 1.10E−05 3′ss Br. 23545541- 23545527- ACCGACAGTTTT ACCCACAGGTAT 23556543 23556543 TTTTTTTCAGGT ATGTCCTCATTT ATAT (11) TCCT (12) 7 chr10: chr10: TACCTCTGGTTC TACCTCTGGTTC 0 46 5.55 3.63E−09 3′ss Br. 99214556- 99214556- CTGTGCAGTCTT CTGTGCAGTTCT 99215395 99215416 CGCCCCTCTTTT GTGGCACTTGCC CTTA (13) CTGG (14) 8 chr18: chr18: TTGGACCGGAAA TTGGACCGGAAA 0 44 5.49 4.30E−09 3′ss Br. 683395- 683380- AGACTTTGAGTC AGACTTTGATGA 685920 685920 TCTTTTTGCAGA TGGATGCCAACC TGAT (15) AGCG (16) 9 chr17: chr17: ACCCAAGCCTTG ACCCAAGCCTTG 0 44 5.49 1.50E−07 exon Br. 40714237- 40714237- AGGTTTCATTTC AGGTTTCAGCCT incl. 40714373 40714629 CCCCTCCCAGGA GGGCAGCATGGC TTTC (17) CGTA (18) 10 chr5: chr5: AGCATTGCTAGA AGCATTGCTAGA 0 41 5.39 4.86E−09 3′ss Br. 139815842- 139815842- AGCAGCAGCTTT AGCAGCAGGAAT 139818078 139818045 TGCAGATCCTGA TGGCAAATTGTC GGTA (19) AACT (20) 11 chr1: chr1: CAAGTATATGAC CAAGTATATGAC 0 39 5.32 1.31E−10 3′ss Br. 245246990- 245246990- TGAAGAAGATCC TGAAGAAGGTGA 245288006 245250546 TGAATTCCAGCA GCCTTTTTCTCA AAAC (21) AGAG (22) 12 chr3: chr3: TGCAGTTTGGTC TGCAGTTTGGTC 0 36 5.21 9.63E−09 3′ss Br. 9960293- 9960293- AGTCTGTGCCTT AGTCTGTGGGCT 9962150 9962174 CCTCACCCCTCT CTGTGGTATATG CCTC (23) ACTG (24) 13 chr1: chr1: TCTTTGGAAAAT TCTTTGGAAAAT 0 29 4.91 3.27E−07 3′ss Br. 101458310- 101458296- CTAATCAATTTT CTAATCAAGGGA 101460665 101460665 CTGCCTATAGGG AGGAAGATCTAT GAAG (25) GAAC (26) 14 chr7: chr7: GTATCAAAGTGT GTATCAAAGTGT 0 28 4.86 5.02E−05 3′ss Br. 94157562- 94157562- GGACTGAGATTT GGACTGAGGATT 94162500 94162516 GTCTTCCTTTAG CCATTGCAAAGC GATT (27) CACA (28) 15 chr20: chr20: AGAACTGCACCT AGAACTGCACCT 0 27 4.81 1.50E−07 3′ss Br. 62701988- 62701988- ACACACAGCCCT ACACACAGGTGC 62703210 62703222 GTTCACAGGTGC AGACCCGCAGCT AGAC (29) CTGA (30) 16 chr17: chr17: GGAGCAGTGCAG GGAGCAGTGCAG 0 25 4.70 9.63E−06 3′ss Br. 71198039- 71198039- TTGTGAAATCAT TTGTGAAAGTTT 71199162 71199138 TACTTCTAGATG TGATTCATGGAT ATGC (31) TCAC (32) 17 chr17: chr17: CTATTTCACTCT CTATTTCACTCT 0 25 4.70 5.99E−08 3′ss Br. 7131030- 7131102- CCCCCGAACCTA CCCCCGAAATGA 7131295 7131295 TCCAGGTTCCTC GCCCATCCAGCC CTCC (33) AATT (34) 18 chr20: chr20: TTTGCAGGGAAT TTTGCAGGGAAT 0 25 4.70 2.72E−07 3′ss Br. 35282126- 35282104- GGGCTACATCCC GGGCTACATACC 35284762 35284762 CTTGGTTCTCTG ATCTGCCAGCAT TTAC (35) GACT (36) 19 chr2: chr2: TGACCACGGAGT TGACCACGGAGT 0 25 4.70 1.61E−06 3′ss Br. 232196609- 232196609- ACCTGGGGCCCT ACCTGGGGATCA 232209660 232209686 TTTTTCTCTTTC TGACCAACACGG CTTC (37) GGAA (38) 20 chr17: chr17: AGACCTACCAGA AGACCTACCAGA 0 24 4.64 7.16E−06 3′ss Br. 62574712- 62574694- AGGCTATGTGTT AGGCTATGAACA 62576906 62576906 TATTAATTTTAC GAGGACAACGCA AGAA (39) ACAA (40) 21 chr12: chr12: ATTTGGACTCGC ATTTGGACTCGC 0 23 4.58 8.14E−08 3′ss Br. 105601825- 105601807- TAGCAATGATGT TAGCAATGAGCA 105601935 105601935 CTGTTTATTTTT TGACCTCTCAAT AGAG (41) GGCA (42) 22 chr12: chr12: CATGTGGAATCC CATGTGGAATCC 0 22 4.52 1.87E−04 3′ss Br. 53836517- 53836517- CAATGCCGGCCC CAATGCCGGGCA 53837270 53837174 CTGTCCTCCTCC GCCAGGGCCAAA CCCA (43) TCCA (44) 23 chr22: chr22: CTGGGAGGTGGC CTGGGAGGTGGC 0 22 4.52 2.76E−08 3′ss Br. 19044699- 19044675- ATTCAAAGCCCC ATTCAAAGGCTC 19050714 19050714 ACCTTTTGTCTC TTCAGAGGTGTT CCCA (45) CCTG (46) 24 chr11: chr11: GGATGACCGGGA GGATGACCGGGA 0 21 4.46 4.61E−08 3′ss Br. 71939542- 71939542- TGCCTCAGTCAC TGCCTCAGATGG 71939690 71939770 TTTACAGCTGCA GGAGGATGAGAA TCGT (47) GCCC (48) 25 chr20: chr20: ACATGAAGGTGG ACATGAAGGTGG 0 21 4.46 2.63E−08 3′ss Br. 34144042- 34144042- ACGGAGAGGCTC ACGGAGAGGTAC 34144725 34144743 CCCTCCCACCCC TGAGGACAAATC AGGT (49) AGTT (50) 26 chr6: chr6: AGAGAAGTCGTT AGAGAAGTCGTT 2 64 4.44 2.91E−10 3′ss Br. 31919381- 31919381- TCATTCAAGTCA TCATTCAAGTTG 31919565 31919651 GCTAAGACACAA GTGTAATCAGCT GCAG (51) GGGG (52) 27 chr1: chr1: TCACTCAAACAG TCACTCAAACAG 0 20 4.39 9.99E−07 3′ss Br. 179835004- 179834989- TAAACGAGTTTT TAAACGAGGTAT 179846373 179846373 ATCATTTACAGG GTGACGCATTCC TATG (53) CAGA (54) 28 chr1: chr1: CGATCTCCCAAA CGATCTCCCAAA 0 20 4.39 1.35E−09 3′ss Br. 52880319- 52880319- AGGAGAAGTCTG AGGAGAAGCCCC 52880412 52880433 ACCAGTCTTTTC TCCCCTCGCCGA TACA (55) GAAA (56) 29 chr8: chr8: TTATTTTACACA TTATTTTACACA 0 20 4.39 1.49E−09 3′ss Br. 38095145- 38095145- ATCCAAAGCCAG ATCCAAAGCTTA 38095624 38095606 TTGCAGGGTCTG TGGTGCATTACC ATGA (57) AGCC (58) 30 chr19: chr19: TGCCTGTGGACA TGCCTGTGGACA 0 19 4.32 2.37E−05 3′ss Br. 14031735- 14031735- TCACCAAGCCTC TCACCAAGGTGC 14034130 14034145 GTCCTCCCCAGG CGCCTGCCCCTG TGCC (59) TCAA (60) 31 chr14: chr14: AGTTAGAATCCA AGTTAGAATCCA 0 18 4.25 1.65E−10 3′ss Br. 74358911- 74358911- AACCAGAGTGTT AACCAGAGCTCC 74360478 74360499 GTCTTTTCTCCC TGGTACAGTTTG CCCA (61) TTCA (62) 32 chr19: chr19: ATATGCTGGAAT ATATGCTGGAAT 0 18 4.25 8.07E−08 3′ss Br. 45314603- 45314603- GGTTCCTTGTCA GGTTCCTTACCG 45315482 45315419 CAATGCACGACA ACCGCTCGGGAG CCCG (63) CTCG (64) 33 chr1: chr1: ATCAGAAATTCG ATCAGAAATTCG 0 18 4.25 4.25E−08 3′ss Br. 212515622- 212515622- TACAACAGGTTT TACAACAGCTCC 212519131 212519144 CTTTTAAAGCTC TGGAGCTTTTTG CTGG (65) ATAG (66) 34 chr9: chr9: AAATGAAGAAAC AAATGAAGAAAC 0 18 4.25 1.31E−10 3′ss Br. 125759640- 125759640- TCCTAAAGCCTC TCCTAAAGATAA 125760854 125760875 TCTCTTTCTTTG AGTCCTGTTTAT TTTA (67) GACC (68) 35 chr11: chr11: CATAAAATTCTA CATAAAATTCTA 0 17 4.17 1.35E−06 3′ss Br. 4104212- 4104212- ACAGCTAATTCT ACAGCTAAGCAA 4104471 4104492 CTTTCCTCTGTC GCACTGAGCGAG TTCA (69) GTGA (70) 36 chr12: chr12: GCCTGCCTTTGA GCCTGCCTTTGA 0 17 4.17 3.58E−07 3′ss Br. 113346629- 113346629- TGCCCTGGATTT TGCCCTGGGTCA 113348840 113348855 TGCCCGAACAGG GTTGACTGGCGG TCAG (71) CTAT (72) 37 chr17: chr17: CCAAGCTGGTGT CCAAGCTGGTGT 0 17 4.17 4.19E−04 3′ss Br. 78188582- 78188564- GCGCACAGGCCT GCGCACAGGCAT 78188831 78188831 CTCTTCCCGCCC CATCGGGAAGAA AGGC (73) GCAC (74) 38 chr20: chr20: CTCCTTTGGGTT CTCCTTTGGGTT 0 17 4.17 2.67E−07 3′ss Br. 45354963- 45354963- TGGGCCAGGCCC TGGGCCAGTGAC 45355453 45355502 CAGGTCCCACCA CTGGCTTGTCCT CAGC (75) CAGC (76) 39 chr12: chr12: AATATTGCTTTA AATATTGCTTTA 0 16 4.09 2.79E−07 3′ss Br. 116413154- 116413118- CCAAACAGGGAC CCAAACAGGTCA 116413319 116413319 CCCTTCCCCTTC CGGAGGAGTAAA CCCA (77) GTAT (78) 40 chr14: chr14: CAGTTATAAACT CAGTTATAAACT 0 16 4.09 4.46E−07 3′ss Br. 71059726- 71059705- CTAGAGTGAGTT CTAGAGTGCTTA 71060012 71060012 TATTTTCCTTTT CTGCAGTGCATG ACAA (79) GTAT (80) 41 chr16: chr16: GCCTGCCCCGGA GCCTGCCCCGGA 0 15 4.00 7.77E−06 3′ss Br. 30012851- 30012851- AACTCAAGATGT AACTCAAGATGG 30016688 30016541 TCAGCGATGCAG CGGTGGGACCCC GTAG (81) CCGA (82) 42 chr17: chr17: TTCAGGAGGTGG TTCAGGAGGTGG 0 15 4.00 3.26E−05 3′ss Br. 57148329- 57148308- AGCACCAGATAA AGCACCAGTTGC 57153007 57153007 TTTTTTTCCTCA GGTCTTGTAGTA CACA (83) AGAG (84) 43 chr16: chr16: GGATCCTTCACC GGATCCTTCACC 0 14 3.91 3.01E−07 3′ss Br. 1402307- 1402307- CGTGTCTGTCTT CGTGTCTGGACC 1411686 1411743 TGCAGACAGGTT CGTGCATCTCTT CTGT (85) CCGA (86) 44 chr3: chr3: ATTTGGATCCTG ATTTGGATCCTG 0 14 3.91 8.71E−07 3′ss Br. 196792335- 196792319- TGTTCCTCTTTT TGTTCCTCATAC 196792578 196792578 TTTCTGTTAAAG AACTAGACCAAA ATAC (87) ACGA (88) 45 chr14: chr14: AGATGTCAGGTG AGATGTCAGGTG 0 13 3.81 1.55E−05 3′ss Br. 75356052- 75356052- GGAGAAAGCCTT GGAGAAAGCTGT 75356580 75356599 TGATTGTCTTTT TGGAGACACAGT CAGC (89) TGCA (90) 46 chr18: chr18: AGAAAGAGCATA AGAAAGAGCATA 0 13 3.81 9.84E−07 3′ss Br. 33605641- 33573263- AATTGGAAATAT AATTGGAAGAGT 33606862 33606862 TGGACATGGGCG ACAAGCGCAAGC TATC (91) TAGC (92) 47 chr1: chr1: TCAGCCCTCTGA TCAGCCCTCTGA 0 13 3.81 6.10E−07 3′ss Br. 226036315- 226036255- ACTACAAAGGTG ACTACAAAACAG 226036597 226036597 TTTGTTCACAGA AAGAGCCTGCAA GATC (93) GTGA (94) 48 chr6: chr6: CCGGGGCCTTCG CCGGGGCCTTCG 3 51 3.70 1.35E−09 3′ss Br. 10723474- 10723474- TGAGACCGCTTG TGAGACCGGTGC 10724788 10724802 TTTTCTGCAGGT AGGCCTGGGGTA GCAG (95) GTCT (96) 49 chr2: chr2: CAAGTCCATCTC CAAGTCCATCTC 0 12 3.70 5.71E−03 3′ss Br. 132288400- 132288400- TAATTCAGGGTC TAATTCAGGCAA 132289210 132289236 TGACTTGCAGCC GGCCAGGCCCCA AACT (97) GCCC (98) 50 chr2: chr2: CAAGATAGATAT CAAGATAGATAT 0 12 3.70 4.26E−06 3′ss Br. 170669034- 170669016- TATAGCAGGTGG TATAGCAGAACT 170671986 170671986 CTTTTGTTTTAC TCGATATGACCT AGAA (99) GCCA (100) 51 chr15: chr15: GAAACCAACTAA GAAACCAACTAA 1 24 3.64 4.30E−09 3′ss Br. 59209219- 59209198- AGGCAAAGCCCA AGGCAAAGGTAA 59224554 59224554 TTTTCCTTCTTT AAAACATGAAGC CGCA (101) AGAT (102) 52 chr11: chr11: GGGGACAGTGAA GGGGACAGTGAA 0 11 3.58 5.99E−08 3′ss Br. 57100545- 57100623- ATTTGGTGGCAA ATTTGGTGGGCA 57100908 57100908 GAATGAGGTGAC GCTGCTTTCCTT ACTG (103) TGAC (104) 53 chr1: chr1: CTCAGAGCCAGG CTCAGAGCCAGG 0 11 3.58 3.15E−07 3′ss Br. 35871069- 35871069- CTGTAGAGATGT CTGTAGAGTCCG 35873587 35873608 TTTCTACCTTTC CTCTATCAAGCT CACA (105) GAAG (106) 54 chr2: chr2: GAGGAGCCACAC GAGGAGCCACAC 0 11 3.58 2.22E−07 3′ss Br. 220044485- 220044485- TCTGACAGATAC TCTGACAGTGAG 220044888 220044831 CTGGCTGAGAGC GGTGCGGGGTCA TGGC (107) GGCG (108) 55 chr5: chr5: ACTCGCGCCTCT ACTCGCGCCTCT 0 11 3.58 7.04E−07 3′ss Br. 150411955- 150411944- TCCATCTGTTTT TCCATCTGCCGG 150413168 150413168 GTCGCAGCCGGA AATACACCTGGC ATAC (109) GTCT (110) 56 chrX: chrX: ACTTCCTTAGTG ACTTCCTTAGTG 0 11 3.58 7.37E−07 3′ss Br. 47059013- 47059013- GTTTCCAGGTTG GTTTCCAGGTGG 47059808 47060292 CCAGGGCACTGC TGGTGCTCACCA AGCT (111) ACAC (112) 57 chrX: chrX: GTCTTGAGAATT ACTTCCTTAGTG 0 11 3.58 6.70E−06 5′ss Br. 47059943- 47059013- GGAAGCAGGTGG GTTTCCAGGTGG 47060292 47060292 TGGTGCTCACCA TGGTGCTCACCA ACAC (113) ACAC (112) 58 chr20: chr20: TCCAGAGCCCAC TCCAGAGCCCAC 2 34 3.54 4.87E−09 3′ss Br. 330007- 330007- AGTCCCAGCTGC AGTCCCAGGGGT 330259 330281 ACCTTACCTGCT CCATGATGCCGA CCCC (114) GCTG (115) 59 chr18: chr18: CCAAGTTTTGTG CCAAGTTTTGTG 1 22 3.52 1.96E−05 3′ss Br. 224200- 224179- AAAGAAAGTGTA AAAGAAAGAACA 224923 224923 TGTTTTGTTCAC TCAGATACCAAA GACA (116) CCTA (117) 60 chr11: chr11: TCTTCACAGAAC TCTTCACAGAAC 0 10 3.46 2.99E−08 3′ss Br. 47195466- 47195391- ACACTCAAGTGC ACACTCAACCCC 47196565 47196565 TTGTAGGTCTTG CTGCCTGGGATG GTGC (118) CGCC (119) 61 chr12: chr12: GAGAAGCTCACG TCTTGGAGGAGC 0 10 3.46 4.11E−02 exon Br. 56604352- 56604352- ATTACCAGGCAC CAGTACAGGCAC incl. 56606779 56607741 CTCATTGTGAAC CTCATTGTGAAC ATGC (120) ATGC (121) 62 chr14: chr14: GTGGGGGGCCAT GTGGGGGGCCAT 0 10 3.46 3.25E−08 3′ss Br. 23237380- 23237380- TGCTGCATTTTG TGCTGCATGTAC 23238985 23238999 TATTTTCCAGGT AGTCTTTGCCCG ACAG (122) CTGC (123) 63 chr17: chr17: TACTGAAATGTG TACTGAAATGTG 0 10 3.46 2.49E−05 3′ss Br. 34942628- 34942628- ATGAACATATCC ATGAACATATCC 34943454 34943426 AGGTAATCGAGA AGAAGCTTGGAA GACC (124) GCTG (125) 64 chr1: chr1: GAATCTCTTATC GAATCTCTTATC 0 10 3.46 2.93E−06 3′ss Br. 145581564- 145581564- ATTGATGGTTCC ATTGATGGTTTA 145583935 145583914 TGTTCAGATTGT TTTATGGAGATT GATG (126) CTTA (127) 65 chr5: chr5: CTCCATGCTCAG CTCCATGCTCAG 1 20 3.39 6.76E−06 3′ss Br. 869519- 865696- CTCTCTGGTTTC CTCTCTGGGGAA 870587 870587 TTTCAGGGCCTG GGTGAAGAAGGA CCAT (128) GCTG (129) 66 chr12: chr12: CTTGGAGCTGAC CTTGGAGCTGAC 7 79 3.32 1.30E−08 3′ss Br. 107378993- 107379003- GCCGACGGGGAA GCCGACGGTTTA 107380746 107380746 CTGACAAGATCA TTGCAGGGAACT CATT (130) GACA (131) 67 chr7: chr7: TCCAGCCTGGGC CTATCAAAAGAG 1 19 3.32 4.35E−08 exon Br. 8261028- 8261028- GACAGAAGTCTT GATATGTTTCTT incl. 8267267 8268230 GTCTCAAGAAGA GTCTCAAGAAGA AAAC (132) AAAC (133) 68 chr10: chr10: TGCGGAGCAAGA TGCGGAGCAAGA 0 9 3.32 1.37E−04 3′ss Br. 5497081- 5497081- GTGGACATCGTT GTGGACATAAAC 5498027 5498049 TGTTTCCCATTT TTTACATTTTCC CTCC (134) TGTT (135) 69 chr11: chr11: AGTCCAGCCCCA AGTCCAGCCCCA 0 9 3.32 4.66E−07 3′ss Br. 64900740- 64900723- GCATGGCACCTC GCATGGCAGTCC 64900940 64900940 TCCCCACTCCTA TGTACATCCAGG GGTC (136) CCTT (137) 70 chr19: chr19: CAAGCAGGTCCA CAAGCAGGTCCA 0 9 3.32 1.49E−09 3′ss Br. 5595521- 5595508- AAGAGAGATTTT AAGAGAGAAGCT 5598803 5598803 GGTAAACAGAGC CCAAGAGTCAGG TCCA (138) ATCG (139) 71 chr22: chr22: CTCTCTCCAACC CTCTCTCCAACC 0 9 3.32 8.58E−06 3′ss Br. 39064137- 39064137- TGCATTCTCATC TGCATTCTTTGG 39066874 39066888 TCGCCCACAGTT ATCGATCAACCC GGAT (140) GGGA (141) 72 chr9: chr9: CACCACGCCGAG CACCACGCCGAG 2 28 3.27 2.13E−08 3′ss Br. 125023777- 125023787- GCCACGAGACAT GCCACGAGTATT 125026993 125026993 TGATGGAAGCAG TCATAGACATTG AAAC (142) ATGG (143) 73 chr15: chr15: GCCTCACTGAGC GCCTCACTGAGC 1 18 3.25 5.94E−09 exon Br. 25207356- 25207356- AACCAAGAGTAG AACCAAGAGTGT incl. 25212175 25213078 TGACTTGTCAGG CAGTTGTACCCG AGGA (144) AGGC (145) 74 ch19: chr9: GGGAGATGGATA GGGAGATGGATA 3 35 3.17 6.19E−08 3′ss Br. 35813153- 35813142- CCGACTTGCTCA CCGACTTGTGAT 35813262 35813262 ATTTCAGTGATC CAACGATGGGAA AACG (146) GCTG (147) 75 chr6: chr6: AGGATGTGGCTG AGGATGTGGCTG 1 17 3.17 5.18E−06 3′ss Br. 31602334- 31602334- GCACAGAAGTGT GCACAGAAATGA 31602574 31602529 CATCAGGTCCCT GTCAGTCTGACA GCAG (148) GTGG (149) 76 chr11: chr11: TTCTCCAGGACC TTCTCCAGGACC 0 8 3.17 6.00E−04 3′ss Br. 125442465- 125442465- TTGCCAGACCTT TTGCCAGAGGAA 125445146 125445158 TTCTATAGGGAA TCAAAGACTCCA TCAA (150) TCTG (151) 77 chr13: chr13: AGCTGAAATTTC AGCTGAAATTTC 0 8 3.17 1.20E−06 3′ss Br. 113915073- 113915073- CAGTAAAGGGGG CAGTAAAGCCTG 113917776 113917800 GTTTTATTCTTC GAGATTTGAAAA TTTT (152) AGAG (153) 78 chr16: chr16: GATGTCACTGTG GATGTCACTGTG 0 8 3.17 4.76E−02 3′ss Br. 14966186- 14966186- ACTATCAAGGGC ACTATCAAGTCT 14968874 14968892 CGTCTTTCTTCT TCCATCGACAGT AGGT (154) GAAC (155) 79 c11r2: chr2: TATCCATTCCTG TATCCATTCCTG 0 8 3.17 2.22E−07 3′ss Br. 178096758- 178096736- AGTTACAGTATA AGTTACAGTGTC 178097119 178097119 AACTTCCTTCTC TTAATATTGAAA ATGC (156) ATGA (157) 80 chrX: chrX: TACAAGAGCTGG TACAAGAGCTGG 0 8 3.17 2.14E−05 3′ss Br. 153699660- 153699660- GTGGAGAGGGTC GTGGAGAGGTAT 153699819 153699830 CCAACAGGTATT TATCGAGACATT ATCG (158) GCAA (159) 81 chr19: chr19: AGCCATTTATTT AGCCATTTATTT 3 31 3.00 7.42E−06 3′ss Br. 9728842- 9728855- GTCCCGTGGGAA GTCCCGTGGGTT 9730107 9730107 CCAATCTGCCCT TTTTTCCAGGGA TTTG (160) ACCA (161) 82 chr1: chr1: AGTTACAACGAA AGTTACAACGAA 2 23 3.00 8.51E−06 3′ss Br. 185056772- 185056772- CACCTCAGTGAC CACCTCAGGAGG 185060696 185060710 TCTTTTACAGGA CAATAACAGATG GGCA (162) GCTT (163) 83 chr15: chr15: TCACACAGGATA GCCTCACTGAGC 1 15 3.00 3.25E−08 exon Br. 25212299- 25207356- ATTTGAAAGTGT AACCAAGAGTGT incl. 25213078 25213078 CAGTTGTACCCG CAGTTGTACCCG AGGC (164) AGGC (145) 84 chr11: chr11: CGGCGCGGGCAA CGGCGCGGGCAA 0 7 3.00 1.28E−08 3′ss Br. 62648919- 62648919- CCTGGCGGCCCC CCTGGCGGGTCT 62649352 62649364 CATTTCAGGTCT GAAGGGGCGTCT GAAG (165) CGAT (166) 85 chr11: chr11: CCACCGCCATCG CCACCGCCATCG 0 7 3.00 4.87E−09 3′ss Br. 64877395- 64877395- ACGTGCAGTACC ACGTGCAGGTGG 64877934 64877953 TCTTTTTACCAC GGCTCCTGTACG CAGG (167) AAGA (168) 86 chr19: chr19: CTATGGGCTCAC CTATGGGCTCAC 0 7 3.00 1.24E−03 3′ss Br. 41084118- 41084118- TCCTCTGGTCCT TCCTCTGGTTCG 41084353 41084367 CCTGTTGCAGTT TCGCCTGCAGCT CGTC (169) TCGA (170) 87 chr1: chr1: TATCTCTGGGAA TATCTCTGGGAA 0 7 3.00 3.66E−06 3′ss Br. 35917392- 35917377- AAAACACATTTC AAAACACAGGGA 35919157 35919157 TTTTTTTGCAGG CCTGATGGGGTG GGAC (171) CAGC (172) 88 chr22: chr22: TCATCCAGAGCC TCATCCAGAGCC 0 7 3.00 1.95E−06 3′ss Br. 50966161- 50966146- CAGAGCAGGGGA CAGAGCAGATGC 50966940 50966940 TGTCTGACCAGA AAGTGCTGCTGG TGCA (173) ACCA (174) 89 chr9: chr9: CCAAGGACTGCA CCAAGGACTGCA 0 7 3.00 8.14E−08 3′ss Br. 139837449- 139837395- CTGTGAAGGCCC CTGTGAAGATCT 139837800 139837800 CCGCCCCGCGAC GGAGCAACGACC CTGG (175) TGAC (176) 90 chr1: chr1: CCCGAGCTCAGA CCCGAGCTCAGA 4 38 2.96 2.79E−08 3′ss Br. 3548881- 3548902- GAGTAAATTCTC GAGTAAATATGA 3549961 3549961 CTTACAGACACT GATCGCCTCTGT GAAA (177) CCCA (178) 91 chr19: chr19: GTGCTTGGAGCC GTGCTTGGAGCC 3 29 2.91 3.56E−07 3′ss Br. 55776746- 55776757- CTGTGCAGACTT CTGTGCAGCCTG 55777253 55777253 TCCGCAGGGTGT GTGACAGACTTT GCGC (179) CCGC (180) 92 chr1: chr1: GCTGGACACGCT GCTGGACACGCT 1 14 2.91 2.38E−07 exon Br. 39332671- 39333282- GACCAAGGCATC GACCAAGGTGTT skip 39338689 39338689 ACTTAGGAGCTG GGTAGCCTTATA CTAC (181) TGAA (182) 93 chr2: chr2: CCCCTGAGATGA CCCCTGAGATGA 1 14 2.91 1.82E−07 exon Br. 27260570- 27260570- AGAAAGAGCTCC AGAAAGAGCTCC incl. 27260682 27261013 CTGTTGACAGCT TGAGCAGCCTGA GCCT (183) CTGA (184) 94 chr2: chr2: CTGAACTTTGGG CTGAACTTTGGG 3 28 2.86 7.09E−06 3′ss Br. 233599948- 233599948- CCTGAATGATGT CCTGAATGGCTC 233600472 233612324 GTTTGGACCCCG CGAGCTCTGTCC AATA (185) AGTG (186) 95 chr11: chr11: AGATCGCCTGGC AGATCGCCTGGC 0 6 2.81 4.87E−09 3′ss Br. 3697619- 3697606- TCAGTCAGTTTT TCAGTCAGACAT 3697738 3697738 TCTCTCTAGACA GGCCAAACGTGT TGGC (187) AGCC (188) 96 chr11: chr11: GGAGGTGGACCT GGAGGTGGACCT 0 6 2.81 1.25E−06 3′ss Br. 68363686- 68363686- GAGTGAACAATT GAGTGAACCACC 68367788 68367808 TCTCCCCTCTTT CAACTGGTCAGC TTAG (189) TAAC (190) 97 chr12: chr12: TACAGATGGTAA TACAGATGGTAA 0 6 2.81 8.19E−07 3′ss Br. 72315234- 72315234- AATGCAAGTTTG AATGCAAGGAAT 72316743 72316762 ATTTTTCATATC TGCCACAAGCAG CAGG (191) TCTG (192) 98 chr16: chr16: CCCTGCTCATCA CCCTGCTCATCA 0 6 2.81 5.11E−07 3′ss Br. 685022- 684956- CCTACGGGTCTG CCTACGGGCCCT 685280 685280 TCCCAGGCTCTC ATGCCATCAATG TGGG (193) GGAA (194) 99 chr1: chr1: GGCTCCCATTCT GGCTCCCATTCT 0 6 2.81 3.43E−04 3′ss Br. 155630724- 155630704- GGTTAAAGAGTG GGTTAAAGGCCA 155631097 155631097 TTCTCATTTCCA GTCTGCCATCCA ATAG (195) TCCA (196) 100 chr1: chr1: CTGCACTTATAA CTGCACTTATAA 0 6 2.81 L.50E−06 3′ss Br. 47108988- 47108973- ATATTCAGTGTT ATATTCAGACCC 47110832 47110832 CCACCTTGCAGA GAGGGGAAGCTG CCCG (197) CAGC (198) 101 chr22: chr22: CGCTGGCACCAT CGCTGGCACCAT 0 6 2.81 1.29E−02 3′ss Br. 36627480- 36627512- GAACCCAGTATT GAACCCAGAGAG 36629198 36629198 TCCAGGACCAAG CAGTATCTTTAT TGAG (199) TGAG (200) 102 chr6: chr6: CCCTAGTCTGAT AGAGAAGTCGTT 0 6 2.81 6.01E−04 5′ss Br. 31919565- 31919381- TCCTTTAGGTTG TCATTCAAGTTG 31919651 31919651 GTGTAATCAGCT GTGTAATCAGCT GGGG (201) GGGG (52) 103 chr1: chr1: TTCCCCATCAAC TTCCCCATCAAC 3 26 2.75 6.26E−07 3′ss Br. 19480448- 19480433- ATCAAAAGTTTT ATCAAAAGTTCC 19481411 19481411 GTTGTCTGCAGT AATGGTGGCAGT TCCA (202) AAGA (203) 104 chr11: chr11: CCAGCTGCATTG CCAGCTGCATTG 4 32 2.72 6.93E−04 3′ss Br. 67161081- 67161081- CAAGTTCGGACT CAAGTTCGGGGT 67161193 67161161 GTGAGTCCCTGC GCGGAAGACTCA AGGC (204) CAAC (205) 105 chr12: chr12: GGCCAGCCCCCT GGCCAGCCCCCT 6 41 2.58 1.26E−09 3′ss Br. 120934019- 120934019- TCTCCACGGCCT TCTCCACGGTAA 120934204 120934218 TGCCCACTAGGT CCATGTGCGACC AACC (206) GAAA (207) 106 chr14: chr14: CGCTCTCCGCCT AGGGAGACGTTC 2 17 2.58 1.96E−05 exon Br. 75348719- 75349327- TCCAGAAGGGGT CCTGCCTGGGGT skip 75352288 75352288 CTCCTTATGCCA CTCCTTATGCCA GGGA (208) GGGA (209) 107 chr1: chr1: TTGGAAGCGAAT TTGGAAGCGAAT 1 11 2.58 1.14E−07 3′ss Br. 23398690- 23398690- CCCCCAAGTCCT CCCCCAAGTGAT 23399766 23399784 TTGTTCTTTTGC GTATATCTCTCA AGTG (210) TCAA (211) 108 chr11: chr11: CTACGGCGGTGC CTACGGCGGTGC 0 5 2.58 1.09E−07 3′ss Br. 44957237- 44957213- CCTCCTCACCCC CCTCCTCAGCAT 44958353 44958353 CTTTTCATCCCC CTCCCTGATCAT CGCC (212) GTGG (213) 109 chr12: chr12: CCTGGTCGCAGT CCTGGTCGCAGT 0 5 2.58 9.89E−04 exon Br. 57494682- 57493873- TCAACAAGATGA TCAACAAGGAGA incl. 57496072 57496072 GGAATCTGATGC TCCTGCTGGGCC TCAG (214) GTGG (215) 110 chr16: chr16: CACCAAGCAGAG CACCAAGCAGAG 0 5 2.58 1.04E−07 3′ss Br. 15129410- 15129410- GCTTCCAGTCTG GCTTCCAGGCCA 15129852 15129872 TCTGCCCTTTCT GAAGCCTTTTAA GTAG (216) AAGG (217) 111 chr17: chr17: GGGACTCCCCCA GGGACTCCCCCA 0 5 2.58 9.75E−05 3′ss Br. 41164294- 41164294- AAGACAAGCTTT AAGACAAGGTCC 41164946 41165063 TCTTTCAGTAAA CATTTTCAGTGC TGTA (218) CCAA (219) 112 chr17: chr17: GCACTGCTGTTC GCACTGCTGTTC 0 5 2.58 1.25E−05 3′ss Br. 61511981- 61511955- AACCTCGGCTTC AACCTCGGGGGC 61512446 61512446 TCCCTTCCTCTC AAGTATAGCGCA ACCC (220) TTTG (221) 113 chr19: chr19: ACGAGACCATTG ACGAGACCATTG 0 5 2.58 1.71E−05 3′ss Br. 2247021- 2247021- CCTTCAAGGAGC CCTTCAAGGTGC 2247564 2247592 CCTCTCTGTCCC CGAGCAGAGAGA CCGC (222) TCGA (223) 114 chr21: chr21: AAGATGTCCCTG AAGATGTCCCTG 0 5 2.58 5.11E−07 3′ss Br. 38570326- 38570326- TGAGGATTGTGT TGAGGATTGCAC 38572514 38572532 GTTTGTTTCCAC TGGGTGCAAGTT AGGC (224) CCTG (225) 115 chr6: chr6: AGAGAAGTCGTT AGAGAAGTCGTT 0 5 2.58 2.67E−07 3′ss Br. 31919381- 31919381- TCATTCAATCTG TCATTCAAGTTG 31919551 31919651 ATTCCTTTAGGT GTGTAATCAGCT CAGC (226) GGGG (52) 116 chrX: chrX: AGCCCAGCAGTT AGCCCAGCAGTT 0 5 2.58 5.15E−07 3′ss Br. 48751114- 48751100- CCGAAATGTCTC CCGAAATGCGCC 48751182 48751182 CCTTCTCCAGCG CCCATTCCTGGA CCCC (227) GGAC (228) 117 chr17: chr17: CCCTCCCCCGGC ACCCAAGCCTTG 2 16 2.5 3.35E−04 exon Br. 40714505- 40714237- TCCTGTCGGCCT AGGTTTCAGCCT inc1. 40714629 40714629 GGGCAGCATGGC GGGCAGCATGGC CGTA (229) CGTA (18) 118 chr15: chr15: TGATTCCAAGCA TGATTCCAAGCA 1 10 2.46 1.54E−06 3′ss Br. 25213229- 25213229- AAAACCAGCCTT AAAACCAGGCTC 25219533 25219457 CCCCTAGGTCTT CATCTACTCTTT CAGA (230) GAAG (231) 119 chr2: chr2: CAAGTCCATCTC CAAGTCCATCTC 2 15 2.42 6.24E−03 3′ss Br. 132288400- 132288400- TAATTCAGCCAA TAATTCAGGCAA 132289224 132289236 CTCTCAAGGCAA GGCCAGGCCCCA GGCC (232) GCCC (98) 120 chr7: chr7: CTATCAAAAGAG CTATCAAAAGAG 2 15 2.42 9.00E−05 exon Br. 8267481- 8261028- GATATGTTCATT GATATGTTTCTT inc1. 8268230 8268230 TTAGGAGGCCAA GTCTCAAGAAGA GGCA (233) AAAC (133) 121 chr3: chr3: GTCTTCCAATGG GTCTTCCAATGG 7 41 2.39 2.38E−07 3′ss Br. 148759467- 148759455- CCCCTCAGCCTT CCCCTCAGGAAA 148759952 148759952 TTCTCTAGGAAA TGATACACCTGA TGAT (234) AGAA (235) 122 chr8: chr8: GCACCTCCCCGG GCACCTCCCCGG 4 25 2.38 3.96E−02 exon Br. 144873910- 144873610- GACGCCTGCCCT GACGCCTGTCAC inc1. 144874045 144874045 TGTCTGGAAAGA CGGACTTTGCTG AGTT (236) AGGA (237) 123 chr17: chr17: TGGACCCCAGAC GTCCCGGAACCA 1 9 2.32 5.71E−03 exon Br. 3828735- 3828735- CACACCGGAAGA CATGCACGAAGA inc1. 3831533 3831956 AATGAGCCAGAA AATGAGCCAGAA GTGA (238) GTGA (239) 124 chr11: chr11: TCTGTGTTCCCA TGTATGACGTCA 0 4 2.32 2.08E−03 5′ss Br. 66040546- 66039931- TCGCACAGGAAT CTGACCAGGAAT 66043274 66043274 CCTACGCCAACG CCTACGCCAACG TGAA (240) TGAA (241) 125 chr12: chr12: GGAATATGATCC GGAATATGATCC 0 4 2.32 6.10E−04 3′ss Br. 15272132- 15264351- CACCCTCGTACT CACCCTCGAATC 15273996 15273996 TCTCAAAGAGGA AACCTACCGACA TGGC (242) CCAA (243) 126 chr16: chr16: GAACTGGCACCG GAACTGGCACCG 0 4 2.32 1.02E−06 3′ss Br. 313774- 313774- ACAGACAGTGTC ACAGACAGATCC 313996 314014 CCCTCCCTCCCC TGTTTCTGGACC AGAT (244) TTGG (245) 127 chr19: chr19: TGATGAAGACCT TGATGAAGACCT 0 4 2.32 L.48E−03 3′ss Br. 44116292- 44112259- TTCCCCAGATCT TTCCCCAGGCCC 44118380 44118380 CTTAGGTGAAGA CGAGCATTCCTC CATG (246) TGAT (247) 128 chr1: chr1: CCAGGCCGACAT CCAGGCCGACAT 0 4 2.32 4.27E−07 3′ss Br. 228335400- 228335400- GGAGAGCAGCCC GGAGAGCAGCAA 228336058 228336071 CACCCACAGGCA GGAGCCCGGCCT AGGA (248) GTTT (249) 129 chr20: chr20: ACATGAAGGTGG ACATGAAGGTGG 0 4 2.32 5.15E−07 3′ss Br. 34144042- 34144042- ACGGAGAGTTCT ACGGAGAGGTAC 34144761 34144743 CTGTGACCAGAC TGAGGACAAATC ATGA (250) AGTT (50) 130 chr2: chr2: TTCGTCCATATG TTCGTCCATATG 0 4 2.32 2.38E−03 3′ss Br. 198267783- 198267759- TGCATAAGCTTC TGCATAAGATCC 198268308 198268308 TTCTCTTTTCTC TCGTGGTCATTG TTTT (251) AACC (252) 131 chr3: chr3: AGGGATGGCCAG AGAAGGGAGCGA 0 4 2.32 8.01E−04 5′ss Br. 47969840- 47969840- TGGTAGTGGGTC TACTACAGGGTC 47981988 48019354 TCCAACTGAATT TCCAACTGAATT CCTT (253) CCTT (254) 132 chr4: chr4: CCAATGTGGTTC CCAATGTGGTTC 0 4 2.32 1.00E−05 3′ss Br. 38907482- 38907482- AAAACACATTAT AAAACACAGGTA 38910197 38910212 CTCATCTGCAGG AAAGTGTCTTAA GTAA (255) CTGG (256) 133 ch17: chr7: CCATTGATGCAA CCATTGATGCAA 0 4 2.32 7.45E−03 exon Br. 94227316- 94218044- ACGCAGCAATGG ACGCAGCAGAAC incl. 94228086 94228086 AGTTTCGCTCCT TTGCCACATCAG GTTG (257) ACTC (258) 134 chr8: chr8: GCTGCATCTGGA CAGTGTTAGTGA 0 4 2.32 6.84E−03 5′ss Br. 17873340- 17872349- GGTCCTGGGAAG ATGACTATGAAG 17882869 17882869 CAGAATCTGGTA CAGAATCTGGTA ATAT (259) ATAT (260) 135 chr17: chr17: ACAAGGACACAG ACAAGGACACAG 10 53 2.30 5.76E−06 3′ss Br. 73518592- 73518292- AAAACAAGCCTT AAAACAAGCTGG 73519333 73519333 CCCACACAGGCC AGCACCGCTGCA CTGC (261) CCTC (262) 136 chr16: chr16: AGCTCGGACCAA AGCTCGGACCAA 9 48 2.29 1.29E−03 3′ss Br. 47495337- 47495337- GCGCTCAGTTTT GCGCTCAGCTTA 47497792 47497809 AAAATTGCTATA GCCTGCGACGCT GCTT (263) TATG (264) 137 chr6: chr6: AGGGGGCTCTTT AGGGGGCTCTTT 6 32 2.24 3.39E−03 3′ss Br. 91269953- 91269933- ATATAATGTTTG ATATAATGTGCT 91271340 91271340 TGCCTTTCTTTC GCATGGTGCTGA GCAG (265) ACCA (266) 138 chr15: chr15: GCCCCCAACTGA GCCCCCAACTGA 2 13 2.22 4.76E−03 exon Br. 41130464- 41128480- GAAGCTGGGCTG GAAGCTGGTGCC incl. 41130740 41130740 GAGTGCTGTGGC CTTGGTGTGGTG ACAA (267) GAAG (268) 139 chr17: chr17: GAACGAGATCTC AGTATCAGAAGG 4 21 2.14 6.40E−03 5′ss Br. 2276080- 2275782- ATCCCACTAACT ACAAAAAGAACT 2276246 2276246 ACAAAGAGCTGG ACAAAGAGCTGG AGCT (269) AGCT (270) 140 chr17: chr17: TGAAGGTCCAGG TGAAGGTCCAGG 8 35 2.00 4.45E−02 3′ss Br. 4885470- 4885455- GCATGGAGCCTG GCATGGAGTGTC 4886051 4886051 TCTCCTGGCAGT TCTATGGCTGCT GTCT(271) ACGT(272) 141 chr16: chr16: GGCGGCCGCGCC GGCGGCCGCGCC 2 11 2.00 3.29E−02 exon Br. 1728357- 1728357- GGCTCCAGGAAA GGCTCCAGGGCC incl. 1733509 1735439 TGGCAACTGCTG ATGAAGCCCCCA ACAG(273) GGAG(274) 142 chr11: chr11: CCTTCCAGCTAC CCTTCCAGCTAC 1 7 2.00 1.25E−04 3′ss Br. 2993509- 2993473- ATCGAAACGCAT ATCGAAACTTTA 2997253 2997253 GAGGATGTTGTA CCTAAAGCAGTA TTTC(275) AAAA(276) 143 chr10: chr10: CTTTTCTCTTCT GATGTGATGAAC 0 3 2.00 2.72E−03 5′ss Br. 69583150- 69583150- TTTTATAGGTTG TATCTTCGGTTG 69595149 69597691 AACAAATCCTGG AACAAATCCTGG CAGA(277) CAGA(278) 144 chr11: chr11: GCACTGGGCATT GCACTGGGCATT 0 3 2.00 1.28E−07 3′ss Br. 66053068- 66053007- CAGAAAAGTCTC CAGAAAAGGTTC 66053171 66053171 TCTTCCTCACCC TCCCCGGAGGTG CTGC(279) CTGG(280) 145 chr11: chr11: CTGTCACAGGGG CTGTCACAGGGG 0 3 2.00 2.18E−03 3′ss Br. 77090454- 77090433- AGTTTACGTCTT AGTTTACGGGAA 77090938 77090938 GCATGTCTCTCT TGCCAGAGCAGT TACA(281) GGGC(282) 146 chr12: chr12: GGGTGCAAAAGA GGGTGCAAAAGA 0 3 2.00 2.66E−07 3′ss Br. 57032980- 57033091- TCCTGCAGCCAT TCCTGCAGGACT 57033763 57033763 TCCAGGTTGCTG ACAAATCCCTCC AGGT(283) AGGA(284) 147 chr12: chr12: GGCACCCCAAAA GGCACCCCAAAA 0 3 2.00 9.82E−07 3′ss Br. 58109976- 58109976- GATGGCAGATCA GATGGCAGGTGC 58110164 58110194 GTCTCTCCCTGT GAGCCCGACCAA TCTC(285) GGAT(286) 148 chr17: chr17: GCATCTCAGCCC GCATCTCAGCCC 0 3 2.00 2.72E−07 3′ss Br. 16344444- 16344444- AAGAGAAGTTTC AAGAGAAGGTTA 16344670 16344681 TTTGCAGGTTAT TATTCCCAGAGG ATTC(287) ATGT(288) 149 chr1: chr1: CTTGCCTTCCCA CTTGCCTTCCCA 0 3 2.00 2.32E−04 3′ss Br. 154246074- 154246074- TCCTCCTGCAAA TCCTCCTGAACT 154246225 154246249 CACCTGCCACCT TCCAGGTCCTGA TTCT(289) GTCA(290) 150 chr1: chr1: CTACACAGAGCT CTACACAGAGCT 0 3 2.00 8.14E−08 3′ss Br. 32096333- 32096443- GCAGCAAGGTGT GCAGCAAGCTCT 32098095 32098095 GCACCCAGCTGC GTCCCAAATGGG AGGT(291) CTAC(292) 151 chr2: chr2: ACCTGTTACCAC ACCTGTTACCAC 0 3 2.00 1.17E−04 3′ss Br. 101622533- 101622533- TTTCAAAATTTC TTTCAAAAATCT 101635459 101622811 TGTGCTAAACAG ACAGACAGTCAA TGTT(293) TGTG(294) 152 chr2: chr2: AGACAAGGGATT AGACAAGGGATT 0 3 2.00 3.82E−06 3′ss Br. 26437445- 26437430- GGTGGAAACATT GGTGGAAAAATT 26437921 26437921 TTATTTTACAGA GACAGCGTATGC ATTG(295) CATG(296) 153 chr3: chr3: CAACGAGAACAA CAACGAGAACAA 0 3 2.00 2.29E−07 3′ss Br. 101401353- 101401336- GCTATCAGTTAC GCTATCAGGGCT 101401614 101401614 TTTTACCCCACA GCTAAGGAAGCA GGGC(297) AAAA(298) 154 chr5: chr5: TCTATATCCCCT TCTATATCCCCT 0 3 2.00 1.27E−06 3′ss Br. 177576859- 177576839- CTAAGACGCACT CTAAGACGGACC 177577888 177577888 TCTTTCCCCTCT TGGGTGCAGCCG GTAG (299) CAGG (300) 155 chr6: chr6: TGGAGCCAGTTA TGGAGCCAGTTA 0 3 2.00 9.28E−04 3′ss Br. 31506716- 31506632- CTGGGCAGGTGT CTGGGCAGGTGT 31506923 31506923 GTTTTTGTGACA CTGTACTGGTGA GTCA (301) TGTG (302) 156 chrX: chrX: AAAAGAAACTGA AAAAGAAACTGA 13 54 1.97 1.08E−05 3′ss Br. 129771378- 129771384- GGAATCAGTATC GGAATCAGCCTT 129790554 129790554 ACAGGCAGAAGC AGTATCACAGGC TCTG (303) AGAA (304) 157 chrX: chrX: CAGCACTAGGTT CAGCACTAGGTT 7 30 1.95 8.04E−04 exon Br. 135758876- 135760115- ATAAAGAGGAGT ATAAAGAGAGGA skip 135761693 135761693 CTAGTAAAAGCC TGTCTTATATCT CTAA (305) TAAA (306) 158 chr6: chr6: GCCCCCGTTTTC GCCCCCGTTTTC 4 18 1.93 9.28E−05 3′ss Br. 31936315- 31936315- CTGCCCAGCCCT CTGCCCAGTACC 31936399 31936462 TGTCCTCAGTGC TGAAGCTGCGGG ACCC (307) AGCG (308) 159 chr2: chr2: GCCGCCGCCGCC CACCTTATGAAG 10 40 1.90 4.22E−03 5′ss Br. 97757449- 97757449- GCCGCCAGGCTC TATAGCAGGCTC 97760437 97757599 TGATGCTGGTGT TGATGCTGGTGT CTGG (309) CTGG (310) 160 chr19: chr19: AGTGGCAGTGGC AGTGGCAGTGGC 6 25 1.89 2.97E−03 3′ss Br. 6731065- 6731122- TGTACCAGCCCA TGTACCAGCTCT 6731209 6731209 CAGGAAACAACC TGGTGGAGGGCT CGTA (311) CCAC (312) 161 chr16: chr16: GAGATTCTGAAG GAGATTCTGAAG 4 16 1.77 5.02E−05 3′ss Br. 54954250- 54954322- ATAAGGAGTTCT ATAAGGAGGTAA 54957496 54957496 CTTGTAGGATGC AACCTGTTTAGA CACT (313) AATT (314) 162 chr2: chr2: CCAAGAGACAGC CCCCTGAGATGA 4 16 1.77 3.39E−06 exon Br. 27260760- 27260570- ACATTCAGCTCC AGAAAGAGCTCC incl. 27261013 27261013 TGAGCAGCCTGA TGAGCAGCCTGA CTGA (315) CTGA (184) 163 chr10: chr10: TCAGAGCAGTCG CTACGACAGTGA 10 35 1.71 1.55E−02 5′ss Br. 75290593- 75290593- GGACACAGGACA AGATTCAGGACA 75294357 75296026 CCTGACTGATAG CCTGACTGATAG TGAA (316) TGAA (317) 164 chr1: chr1: CTGTTGTGTCCG CTGTTGTGTCCG 19 63 1.68 5.06E−05 3′ss Br. 155278867- 155278867- TTTTGAAGAGCC TTTTGAAGAATG 155279833 155279854 CTTTGCTCCTCC AACGGAGACCAG CTCA (318) AATT (319) 165 chr16: chr16: CCGGCCCTACAG CCCTCCGCCTCC 6 21 1.65 3.26E−02 exon Br. 630972- 632309- GCTGGCGGATAA TGATGCAGATAA skip 632882 632882 ACCCACTGCCCT ACCCACTGCCCT ACAG (320) ACAG (321) 166 chr16: chr16: GAGATTCTGAAG GAGATTCTGAAG 18 57 1.61 6.30E−07 3′ss Br. 54954239- 54954322- ATAAGGAGGATG ATAAGGAGGTAA 54957496 54957496 CCACTGGAAATG AACCTGTTTAGA TTGA (322) AATT (314) 167 chr14: chr14: TGAAAAGTCCAG TCCTGGAGGAGC 15 47 1.58 1.41E−02 5′ss Br. 39734625- 39736726- AGGAAGAGGTTG TACGCAGGGTTG 39746137 39746137 TGGCAGCACTGC TGGCAGCACTGC CTGA (323) CTGA (324) 168 chr13: chr13: GTCATGGCAGAA CTATAGCTACTG 10 32 1.58 1.25E−02 exon Br. 21157158- 21164006- GACCTCCATCCA GATATGGGTCCA skip 21165105 21165105 AGACATCTCTGG AGACATCTCTGG CATC (325) CATC (326) 169 chr17: chr17: CCGGAGCCCCTT CCGGAGCCCCTT 5 17 1.58 4.45E−02 3′ss Br. 45229302- 45229284- CAAAAAAGACTT CAAAAAAGTCTG 45232037 45232037 TTCGTGTTTTAC TTGCCAGAATCG AGTC (327) GCCA (328) 170 chr16: chr16: CCACAGATACTA CCACAGATACTA 3 11 1.58 1.99E−02 3′ss Br. 47484364- 47462809- TTAGGAGGCCAT TTAGGAGGGAAT 47485306 47485306 ACCACCCTGAAC TTATCATGGCAT GCGC (329) CCAG (330) 171 chr12: chr12: TGTTCAAGTTCC CCTGGTCGCAGT 1 5 1.58 1.50E−04 exon Br. 57493873- 57493873- CAAAGCAGGAGA TCAACAAGGAGA incl. 57494628 57496072 TCCTGCTGGGCC TCCTGCTGGGCC GTGG (331) GTGG (215) 172 chr16: chr16: ACTCCCAGCTCA ACTCCCAGCTCA 0 2 1.58 6.10E−05 3′ss Br. 56403209- 56403239- ATGCAATGGTTC ATGCAATGGCTC 56419830 56419830 CATACCATCTGG ATCAGATTCAAG TACT (332) AGAT (333) 173 chr17: chr17: ATCACTGTGACT ATCACTGTGACT 0 2 1.58 4.98E−05 3′ss Br. 80013701- 80013701- TCCCTGAGGTCT TCCCTGAGCTGC 80013861 80013876 CTGCTCCTCAGC TGTCCCCCAGCA TGCT (334) ACGT (335) 174 chr18: chr18: ATCCTCTCAATC ATCCTCTCAATC 0 2 1.58 4.76E−02 3′ss Br. 51729496- 51715381- AAAATAAGTTTG AAAATAAGGGTA 51731367 51731367 TGTGCACTTTTC AACCAGACTTGA TGCT (336) ATAC (337) 175 chr1: chr1: CTATTCCTTTAT CTATTCCTTTAT 0 2 1.58 5.34E−04 3′ss Br. 145109684- 145109684- TGAATTTGTTTT TGAATTTGATAC 145112354 145112372 CTTCATCATTCT TTTCATTCAGAA AGAT (338) AACC (339) 176 chr2: chr2: AGTCATACCTGG AGTCATACCTGG 0 2 1.58 3.46E−03 3′ss Br. 242274627- 242274627- AGCAGCAGTTTG AGCAGCAGAAAA 242275373 242275389 TTTCTTTTCTAG AATTGAAAGAAC AAAA (340) TGTC (341) 177 chr3: chr3: GCAACCAGTTTG GCAACCAGTTTG 0 2 1.58 1.37E−04 3′ss Br. 49395199- 493951S0- GGCATCAGCTGC GGCATCAGGAGA 49395459 49395459 CCTTCTCTCCTG ACGCCAAGAACG TAGG (342) AAGA (343) 178 chr4: chr4: CCATGGTCAAAA CCATGGTCAAAA 0 2 1.58 3.60E−05 3′ss Br. 152022314- 152022314- AATGGCAGCACC AATGGCAGACAA 152024139 152024022 AACAGGTCCGCC TGATTGAAGCTC AAAT (344) ACGT (345) 179 chr5: chr5: GCCTGATGCCCG GCCTGATGCCCG 0 2 1.58 1.29E−02 exon Br. 1323984- 1324928- AATTTCAGGCCA AATTTCAGTTTG skip 1325865 1325865 TGAAGTACTTGT GCACTTACAGCG CATA (346) AATC (347) 180 chr5: chr5: AGATTGAAGCTA AGATTGAAGCTA 0 2 1.58 6.18E−06 3′ss Br. 132439718- 132439718- AAATTAAGTTTT AAATTAAGGAGC 132439902 132439924 CTGTCTTACCCA TGACAAGTACTT TTCC (348) GTAG (349) 181 chr5: chr5: AGCACAAGCTAT AGCACAAGCTAT 0 2 1.58 5.76E−06 3′ss Br. 44813384- 44813384- GTATCAAGCATA GTATCAAGGATT 44814996 44815014 ACTTTCTTCTAC CTGGAGTGAAGC AGGA (350) AGAT (351) 182 chr6: chr6: AGATGTAAAAGT AGATGTAAAAGT 0 2 1.58 5.43E−04 3′ss Br. 52546712- 52546712- GTCACTGTTTTG GTCACTGTTTAC 52548863 52548875 GTTTTCAGTTAC AGCTTTCTTCCT AGCT (352) GGCT (353) 183 chr7: chr7: CTGCAGCCTCCG CCATTGATGCAA 0 2 1.58 8.78E−03 exon Br. 94218044- 94218044- CCTCCCAGGAAC ACGCAGCAGAAC incl. 94227241 94228086 TTGCCACATCAG TTGCCACATCAG ACTC (354) ACTC (258) 184 chr15: chr15: AGGATGATGCAG AGGATGATGCAG 10 28 1.4 1.70E−03 3′ss Br. 59373483- 59373483- CATCCAACTGGT CATCCAACGCGG 59376300 59376327 CTTTTTGTGTTC GCACATGAACGC TGTG (355) CCCC (356) 185 chr1: chr1: TGGTGAAATGGA TGGTGAAATGGA 12 33 1.39 1.25E−03 3′ss Br. 153925126- 153925111- CCCCAAAGTCTT CCCCAAAGTACC 153925280 153925280 TCTCTTTCAAGT TGCTATTGAGGA ACCT (357) GAAC (358) 186 chr1: chr1: AGCTTAAAGAAC GATCAAGGCAAC 9 25 1.38 3.31E−02 exon Br. 151739775- 151740709- TGTATTCGTTTG CGGGAAAGTTTG skip 151742647 151742647 ACTGCAACCCTG ACTGCAACCCTG GAGT (359) GAGT (360) 187 chr19: chr19: AACACACCAACT AACACACCAACT 1 4 1.32 8.52E−04 3′ss Br. 47342877- 47342835- TTGTGGAGGTCC TTGTGGAGTTCC 47349249 47349249 TGGCAATCTCCG GGAACTTTAAGA TTGC (361) TCAT (362) 188 chr15: chr15: GCGGGTCTGCAG GTTCCAGGTCCT 5 13 1.22 5.55E−04 exon Br. 75631685- 75632219- CCTACGCAAACT CCTGGCAGAACT skip 75632305 75632305 GAAGCAGGCCCA GAAGCAGGCCCA GACC (363) GACC (364) 189 chr1: chr1: CCCGCTGCCCCA ATTCTGATATAG 5 13 1.22 1.52E−02 exon Br. 212459633- 212502673- GCTCAAAGATCA TAAAAATGATCA skip 212506838 212506838 GTGCTAACATCT GTGCTAACATCT TCCG (365) TCCG (366) 190 chr22: chr22: ATGAGTTTCCCA ATGAGTTTCCCA 2 6 1.22 1.59E−03 3′ss Br. 30976673- 30976688- CCGATGGGGAGG CCGATGGGGAGA 30976998 30976998 AAGACCGCAGGA TGTCAGCGCAGG AGGA (367) AGGA (368) 191 chr7: chr7: AGTTTATTTAAC AGTTTATTTAAC 2 6 1.22 3.40E−02 exon Br. 80535232- 80458061- ATTTGATGAGCC ATTTGATGAACT incl. 80545994 80545994 TACCTTGTACAA TCGAGAAACCAA TGCT (369) GACC (370) 192 chr8: chr8: CCACCTAGCAGC CCACCTAGCAGC 2 6 1.22 1.17E−03 intron Br. 145153766- 145153691- CACCAGAGACCA CACCAGAGGTTA reten- 145153768 145153768 GAGGTGGCACAG CAAGGGGAGAGT tion GCAG (371) GGCC (372) 193 chr9: chr9: TCCAGGATCCTG GGCAGCGGAGGG 2 6 1.22 8.61E−03 exon Br. 96285645- 96278551- AGGCATGGCCAT GCGACAAACCAT incl. 96289436 96289436 ATCAGCGGGAAC ATCAGCGGGAAC AAGA (373) AAGA (374) 194 chr2: chr2: GGCAACTTCGTT GGCAACTTCGTT 20 47 1.19 5.26E−03 3′ss Br. 106781255- 106781240- AATATGAGCTTT AATATGAGGTCT 106782511 106782511 CTACTCAACAGG ATCCAGGAAAAT TCTA (375) GGTG (376) 195 chr19: chr19: GGAGCCTGGGCA GGAGCCTGGGCA 6 15 1.19 1.98E−02 3′ss Br. 7976215- 7976215- TCTCGTTGCCCT TCTCGTTGGTGG 7976299 7976320 GCCCGTCTCCCT AGCTGGCAACAG CCCA (377) GACA (378) 196 chr11: chr11: CTGGTGTGCTTG CTGGTGTGCTTG 3 8 1.17 4.87E−02 exon Br. 9161795- 9161401- GGAGCCAGGGTT GGAGCCAGAGAT incl. 9163486 9163486 ATCATGAAGATT CACCTCCTACAC AAAT (379) CACT (380) 197 chr1: chr1: ATTGGAGGAGCT ATTGGAGGAGCT 10 23 1.13 3.12E−03 exon Br. 160252899- 160253429- TCTGGAAAGATG TCTGGAAAGTGC skip 160254844 160254844 CCCTCTTCGCTT TCTTGATGATTT CCCA (381) CGAT (382) 198 chr19: chr19: AATGACGTGCTG AATGACGTGCTG 7 16 1.09 1.69E−02 3′ss Br. 16641724- 16641691- CACCACTGGGCC CACCACTGCCAG 16643408 16643408 CTGACGCGCGGA CGCAAGCAGGCC AAGT (383) CGGG (384) 199 chr3: chr3: GCCTGGGGTGGA GCCTGGGGTGGA 9 20 1.07 3.01E−02 exon Br. 39141945- 39141994- GAGGGCAGCCCC GAGGGCAGTCTG skip 39142237 39142237 CCAGCTACCACA GGATGTGGCATT AGAA (385) GGCT (386) 200 chr2: chr2: GGAAATGGGACA GGAAATGGGACA 11 24 1.06 3.05E−03 3′ss Br. 230657846- 230657861- GGAGGCAGAGGA GGAGGCAGCTTT 230659894 230659894 TCACAGGCTTTA TCTCTCAACAGA AAAT (387) GGAT (388) 201 chr10: chr10: AGACCGACTGCC AGACCGACTGCC 5 11 1.00 2.09E−02 exon Br. 123718925- 123719110- AGTAATAGGAGA AGTAATAGAGCC skip 123719872 123719872 TTGTGAAGACCT TGTTAGTATTAA TTGA (389) TGAA (390) 202 chr1: chr1: TCATGCTAGCCG TCATGCTAGCCG 5 11 1.00 3.31E−02 exon Br. 44064584- 44064584- AGGCCCAGTGGC AGGCCCAGGAAA incl. 44067741 44069086 GGCCAGAGGAGT CCACTATCAGCG CCGA (391) GCCT (392) 203 chr1: chr1: GAAGGCAGCTGA GAAGGCAGCTGA 4 9 1.00 1.37E−03 3′ss Br. 11131045- 11131030- GCAAACAGTTCT GCAAACAGCTGC 11132143 11132143 CTCCCTTGCAGC CCGGGAACAGGC TGCC (393) AAAG (394) 204 ch16: chr6: GCCAACAGCCAA GCCAACAGCCAA 3 7 1.00 6.32E−03 exon Br. 109690220- 109691670- TTCTACAGGTAC TTCTACAGCTAA skip 109697276 109697276 AACAAATAACAC ACCCACAGTTCA TGTG (395) GCCC (396) 205 chr17: chr17: CCCATCAACTGC CCCATCAACTGC 2 5 1.00 4.46E−02 exon Br. 37873733- 37873733- ACCCACTCCCCT ACCCACTCCTGT skip 37879571 37876039 CTGACGTCCATC GTGGACCTGGAT ATCT (397) GACA (398) 206 chr17: chr17: GCGGAAAGAATT GCGGAAAGAATT 2 5 1.00 4.49E−02 3′ss Br. 5250220- 5250220- GCATGAAGAGCG GCATGAAGTTTG 5253766 5253745 ACAACAACACAA CCATCTCTTGGA CCAG (399) GCAA (400) 207 chr1: chr1: TGTGGGAATTAC AAGAAGGGATGG 2 5 1.00 7.58E−03 exon Br. 27260910- 27250657- AATTCAAGCTTA CAGAGAAGCTTA incl. 27267947 27267947 TCACACAGACTT TCACACAGACTT TCAG (401) TCAG (402) 208 chr5: chr5: CTTCCTCAAGTC CTTCCTCAAGTC 1 3 1.00 1.35E−02 3′ss Br. 176759270- 176759247- GCCCAAAGCTCC GCCCAAAGACAA 176761284 176761284 CCCGTTTCTTCT CGTGGACGACCC CCCC (403) CACG (404) 209 chr7: chr7: TCTTCGCTGGTG TCTTCGCTGGTG 1 3 1.00 8.43E−03 exon Br. 44619227- 44620838- GCAAACTGTATC GCAAACTGCGGG skip 44621047 44621047 GTGAAGAGCGCT TGCATCTCGACA TCCG (405) TCCA (406) 210 chr1: chr1: GCAAGAAGTACA GCAAGAAGTACA 0 1 1.00 9.69E−03 3′ss Br. 165619201- 165619201- AAGTGGAGTATG AAGTGGAGTATC 165620230 165620250 TGCTTTGTTGTG CTATCATGTACA ACAG (407) GCAC (408) 211 chr3: chr3: TGTAGGAGCAAT TGTAGGAGCAAT 0 1 1.00 2.54E−04 3′ss Br. 42826828- 42826812- GACTGTTGCATT GACTGTTGGTAT 42827519 42827519 CTTTTTCTTTAG GGGCTATTCCAT GTAT (409) GTAT (410) 212 chr8: chr8: CCTTCCTGGATC AAGTGCAGATAG 0 1 1.00 5.33E−04 exon Br. 117738411- 117738411- CCCCTAAGGTGG ATGGCCTTGTGG incl. 117746515 117767904 TATTAAAGATAA TATTAAAGATAA TCAA (411) TCAA (412) 213 chrX: chrX: CAGGTCTAACTC CAGGTCTAACTC 0 1 1.00 1.53E−02 3′ss Br. 54835809- 54835809- GCTTCCAGGCCC GCTTCCAGGCTG 54836550 54836154 CAGCAGATGAAC AAGCTTCAGAAA CTGA (413) AGGA (414) 214 chr!6: chr16: CCTCCCCATACC GCCTGCCCCGGA 10 20 0.93 3.40E−02 exon Br. 30012361- 30012851- TGAGCTCGATGG AACTCAAGATGG skip 30016541 30016541 CGGTGGGACCCC CGGTGGGACCCC CCGA (415) CCGA (82) 215 chr6: c1u6: GCAAAAGGATAT GCAAAAGGATAT 10 20 0.93 2.78E−02 3′ss Br. 43006222- 43006210- ACCAGGAGCATT ACCAGGAGGGGT 43006303 43006303 TATTTCAGGGGT CCTCAAGATTCG CCTC (416) AGAT (417) 216 chr6: chr6: CACTCCAATTTA CACTCCAATTTA 9 18 0.93 1.40E−02 exon Br. 135517140- 135517140- TAGATTCTGATT TAGATTCTTTCT incl. 135518098 135520045 CTTCATCATGGT TAAACACTTCCA GTGA (418) GTAA (419) 217 chr7: chr7: TGAGAGTCTTCA TGAGAGTCTTCA 45 85 0.90 3.07E−04 3′ss Br. 99943591- 99943591- GTTACTAGTTTG GTTACTAGAGGC 99947339 99947421 TCTTTCCTAGAT GGATTTCCCTGA CCAG (420) CTGA (421) 218 chr12: chr12: TTAACAGCATTT CCCAGTCATTCA 10 19 0.86 1.21E−02 intron Br. 111085013- 111082934- TGTTTTGCGATT ACAGGAAGGATT reten- 111085015 111085015 CCTGCCAGCTCC CCTGCCAGCTCC tion CAGG (422) CAGG (423) 219 chr4: chr4: GATGAATGCTGA GATGAATGCTGA 4 8 0.85 2.40E−02 exon Br. 141300346- 141300346- CATGGATGATCT CATGGATGCAGT skip 141302115 141300722 CTCTGCAAGAGT TGATGCTGAAAA AGAT (424) TCAA (425) 220 chr10: chr10: GTCAATGCTTCC GTCAATGCTTCC 18 33 0.84 3.71E−02 3′ss Br. 114905856- 114905856- ATGTCCAGCTTT ATGTCCAGGTTC 114910741 114910756 CTGTCTTCTAGG CCTCCCCATATG TTCC (426) GTCC (427) 221 chr16: chr16: TATGGCAAGGAG TATGGCAAGGAG 7 13 0.81 2.25E−02 3′ss Br. 30767593- 30767593- GTCGACCTTCTC GTCGACCTCTGG 30767675 30767687 TTTCCCAGCTGG GCCTGTGGGGTG GCCT (428) ATCT (429) 222 chr3: chr3: TGGTTTTACCTC TGGTTTTACCTC 7 13 0.81 5.98E−03 3′ss Br. 128890351- 128890381- GGATAGAGACAT GGATAGAGGTTT 128890476 128890476 TTGTTATCGCTG CCAGTTTGTTTC TGGT (430) CTCG (431) 223 chr1: chr1: GAATCCGTATCT GAATCCGTATCT 34 60 0.80 2.74E−04 3′ss Br. 155278756- 155278756- GGGAACAGAGCC GGGAACAGAATG 155279833 155279854 CTTTGCTCCTCC AACGGAGACCAG CTCA (432) AATT (433) 224 chr20: chr20: TCCAGGAGTTCC TTTGACTAGGGT 22 39 0.80 1.59E−02 exon Br. 264722- 264722- AGGTTCCGTGTT CCAACCAGTGTT skip 270899 270199 TCACTTCAAGCC TCACTTCAAGCC CACT (434) CACT (435) 225 chr1: chr1: GGGCCTGATGAA GGGCCTGATGAA 30 52 0.77 2.84E−03 exon Br. 53370762- 53372283- TGACATCGCTTC TGACATCGCAGC skip 53373539 53373539 CTCGGCAGTCAT CTTCCCTGCACC GGGA (436) CACC (437) 226 chr4: chr4: AGCCCCAGGATG AGCCCCAGGATG 16 28 0.77 1.45E−02 exon Br. 5815889- 5815889- CCTCGCAGCTCT CCTCGCAGACGT skip 5825343 5819937 CGGAAGAACTGG GCCTTCTGCCAT TTGT (438) GATT (439) 227 chr20: chr20: ACTTGCCTGTGA ACTTGCCTGTGA 15 26 0.75 1.83E−03 3′ss Br. 47741142- 47741124- ATTTCGAGTCTT ATTTCGAGGTGG 47752369 47752369 TCCCTCTGAAAC CCCGGGAGAGTG AGGT (440) GCCC (441) 228 chrX: chrX: TACCCGGGACAA TACCCGGGACAA 2 4 0.74 4.57E−02 3′ss Br. 48933637- 48933604- CCCCAAGGCCGC CCCCAAGGGGCT 48934088 48934088 CCACCCCACCCC CTGTGACCTCTG CCAT (442) CCCC (443) 229 chr1: chr1: CATAGTGGAAGT CATAGTGGAAGT 39 64 0.70 4.20E−07 3′ss Br. 67890660- 67890642- GATAGATCTTCT GATAGATCTGGC 67890765 67890765 TTTTCACATTAC CTGAAGCACGAG AGTG (444) GACA (445) 230 chr1: chr1: GCTGTACCTTCA GCTGTACCTTCA 18 29 0.66 2.84E−03 3′ss Br. 156705701- 156705701- GGAACAGGCCCT GGAACAGGGTTT 156706410 156706423 TTCTCCCAGGTT CCATGCTGAGCT TCCA (446) CCTG (447) 231 chr10: chr10: TAAAGCGACTCA TAAAGCGACTCA 29 46 0.65 1.78E−02 exon Br. 101507147- 101507147- TTGAGCAGGAGG TTGAGCAGGCAA skip 101514285 101510125 TGGTATAACAGA AAGGCAGGATTG CAGA (448) TGGT (449) 232 chr12: chr12: TGGGAATCTGGC TGGGAATCTGGC 31 49 0.64 3.09E−04 3′ss Br. 117595889- 117595868- CAGAGAAGTCTT CAGAGAAGGTGC 117603289 117603289 TCTGTCTTGTTT TTGACATCCTCC TGAA (450) AGCA (451) 233 chr2: chr2: AGAAAACATCGA AGAAAACATCGA 8 13 0.64 2.66E−02 exon Br. 114472772- 114475427- ATTCAGAGCTTG ATTCAGAGAGTT skip 114476730 114476730 ATAATGGAACTA CCAGAAGACAGC TACA (452) GAAC (453) 234 chr1I: chr11: CGTCCGCCAGTC AGCCGGGCGTTG 34 53 0.63 1.78E−02 5′ss Br. 504996- 504996- GTCCCGAGGCAT GGGGAAAGGCAT 507112 506608 GAAGAACTCTTG GAAGAACTCTTG ACTG (454) ACTG (455) 235 chrX: chrX: ACTAATCTTCAG CAAACACCTCTT 14 22 0.62 2.22E−04 exon Br. 123224814- 123224614- CATGCCATTCGG GATTATAATCGG incl. 123227867 123227867 CGTGGCACAAGC CGTGGCACAAGC CTAA (456) CTAA (457) 236 chr9: chr9: CACCACAAAATC CACCACAAAATC 37 57 0.61 6.00E−04 3′ss Br. 140622981- 140622981- ACAGACAGCTTG ACAGACAGCAGC 140637822 140637843 CTTGCCTTTTGT TGCAGTATCTCG TTTA (458) GAAG (459) 237 chr2: chr2: CTCCTACTACAC AGAGCTCAAAGA 34 52 0.60 2.66E−02 exon Br. 152324660- 152325065- AATCTAAGATTT AGTGTTTAATTT skip 152325154 152325154 CAGAAATGGCCA CAGAAATGGCCA AAGA (460) AAGA (461) 238 chr12: chr12: ATTTCCAGAGGA ATTTCCAGAGGA 49 74 0.58 1.10E−04 3′ss Br. 95660408- 95660408- TTTACACTTTTG TTTACACTGGTC 95663814 95663826 CTTGACAGGGTC AGTGCTGCTTGC AGTG (462) CCAT (463) 239 chr7: chr7: GAGTCGGCGCCG CACAGAGAGCTG 5 8 0.58 4.45E−02 exon Br. 44880611- 44880611- AGAACATGTTTC GGCTACAGTTTC skip 44887567 44882875 CTGTGGGCCGCA CTGTGGGCCGCA TCCA (464) TCCA (465) 240 chr10: chr10: TGACGTTCTCTG TGACGTTCTCTG 46 68 0.55 4.09E−04 3′ss Br. 75554088- 75554088- TGCTCCAGTGGT TGCTCCAGGTTC 75554298 75554313 TTCTCCCACAGG CCGGCCCCCAAG TTCC (466) TCGC (467) 241 chrX: chrX: CAAACACCTCTT CAAACACCTCTT 14 21 0.55 2.21E−02 exon Br. 123224614- 123224614- GATTATAACACG GATTATAATCGG incl. 123224703 123227867 CAGGTAACATGG CGTGGCACAAGC ATGT (468) CTAA (457) 242 chr2: chr2: TACTCCAGCTTC TACTCCAGCTTC 30 44 0.54 8.18E−03 3′ss Br. 86398468- 86398435- AGCAACAGCACC AGCAACAGCAGG 86400772 86400772 TACAGAAGCGGC TGATACCCTGTC TCAA (469) GGTC (470) 243 chr17: chr17: TCTCAGCTGACG GGCATGCAACCA 13 19 0.51 4.21E−03 exon Br. 47882807- 47886570- AATGCAAGGCAC GGCACCAGGCAC skip 47888837 47888837 CAACGGAGAGAC CAACGGAGAGAC AGCT (471) AGCT (472) 244 chr1: chr1: TCAAATCATTTA TCAAATCATTTA 9 13 0.49 3.77E−02 3′ss Br. 109743522- 109743522- CCTCCAAGCAGC CCTCCAAGAGGA 109745534 109745565 CAGCTCCTGTCA CTCCTGATGGAT CCAT (473) TTGA (474) 245 chr11: chr11: AGCAAAAAGGGG AGCAAAAAGGGG 35 49 0.47 2.40E−02 3′ss Br. 502249- 502181- TGTCTCAGAATC TGTCTCAGGCCA 504823 504823 TCCGGCCTGTGA CTCTTCACCTCC AACT (475) ACCA (476) 246 chr6: chr6: TGTTGCCTCCGC TGGTCATGGCCA 44 60 0.44 5.91E−04 exon Br. 31611971- 31611971- GGCCGCAGGACA AACCCTGGGACA incl. 31612083 31612301 GCAGGTGCCAGG GCAGGTGCCAGG CTTC (477) CTTC (478) 247 chr20: chr20: TGCCTAAGGCGG TGCCTAAGGCGG 63 84 0.41 4.16E−05 3′ss Br. 30310151- 30310133- ATTTGAATCTCT ATTTGAATAATC 30310420 30310420 TTCTCTCCCTTC TTATCTTGGCTT AGAA (479) TGGA (480) 248 chr6: chr6: TGGTCATGGCCA TGGTCATGGCCA 51 68 0.41 4.27E−03 exon Br. 31612191- 31611971- AACCCTGGGCTC AACCCTGGGACA incl. 31612301 31612301 CACCCTCATCCA GCAGGTGCCAGG GCTG (481) CTTC (478) 249 chr10: chr10: TGCAGATTCCAA CCTTCCACCCAA 49 63 0.36 4.56E−02 exon Br. 34649187- 34649187- AAGAAACGAAAG GGGAACTGAAAG incl. 34661425 34663801 CAGAAGATGAGG CAGAAGATGAGG ATAT (482) ATAT (483) 250 chr4: chr4: AGGAGGGCCCCC AGGAGGGCCCCC 43 54 0.32 1.35E−02 3′ss Br. 860289- 860322- TGCCGCTGGCAA TGCCGCTGCTGA 860743 860743 CAACTCCCAGCC CCCCTTTGGCCC CTGC (484) GCTT (485) 251 chr8: chr8: AACAACTGCCCA AACAACTGCCCA 3 4 0.32 4.44E−02 3′ss Br. 99054946- 99055003- GCTTTGAGTGGC GCTTTGAGGAAA 99057170 99057170 AATAATATTGAA TCTGAAATAGAG CTGG (486) TACT (487) 252 chr8: chr8: GTTGTGCCCATG GTTGTGCCCATG 66 81 0.29 4.37E−02 exon Br. 48694815- 48691654- ACCTCCAGGTTA ACCTCCAGTGAT incl. 48694938 48694938 GGATTAATTGAG CCCAGGGCACCG TGGC (488) CCGT (489) 253 chr20: chr20: GTTAATGGGTTT GTTAATGGGTTT 57 68 0.25 2.24E−02 exon Br. 57470739- 57470739- AATGGAGAGGGC AATGGAGATGAG incl. 57473995 57478585 GGCGAAGAGGAC AAGGCAACCAAA CCGC (490) GTGC (491) 254 chr20: chr20: GCAAGGAGCAAC GTTAATGGGTTT 59 69 0.22 4.34E−03 exon Br. 57474040- 57470739- AGCGATGGTGAG AATGGAGATGAG incl. 57478585 57478585 AAGGCAACCAAA AAGGCAACCAAA GTGC (492) GTGC (491) 255 chr19: chr19: AGTTTGAGATGA AGTTTGAGATGA 79 91 0.2 2.28E−02 exon Br. 17339118- 17339118- AGCGAATGGATC AGCGAATGCTCC incl. 17339611 17339817 CTGGCTTCCTGG CCCTACCAGGGG ACAA (493) TCGC (494) 256 chrX: chrX: AGAAACCTTGAA AGAAACCTTGAA 84 95 0.18 4.29E−02 exon Br. 2209644- 2310515- CGACAAAGTGGA CGACAAAGAGAC skip 2326785 2326785 ATTTTTATACTG GTGAGTCTTGCT TGAC (495) GTGT (496) 257 chrY: chrY: AGAAACCTTGAA AGAAACCTTGAA 84 95 0.18 4.29E−02 exon Br. 2159644- 2260515- CGACAAAGTGGA CGACAAAGAGAC skip 2276785 2276785 ATTTTTATACTG GTGAGTCTTGCT TGAC (495) GTGT (496) 258 chr11: chr11: ACCCCTTTGGCA ACCCCTTTGGCA 0 60 5.93 5.12E−05 3′ss CLL 67815439- 67815439- TCGATCCTGCCC TCGATCCTATTT 67815553 67816345 TTTCCTCAGCAC GGAGCCTGGCTG AAGA (497) CCAA (498) 259 chr2: chr2: TGGGAGGAGCAT TGGGAGGAGCAT 0 59 5.91 7.08E−07 3′ss CLL 97285513- 97285499- GTCAACAGAGTT GTCAACAGGACT 97297048 97297048 TCCCTTATAGGA GGCTGGACAATG CTGG (9) GCCC (10) 260 chr10: chr10: TAAAGTGTTGGC TAAAGTGTTGGC 0 51 5.7 5.10E−07 3′ss CLL 93244412- 93244412- TTTACTTAAATT TTTACTTAATAC 93244921 93244936 TATCTTTACAGA TGCAAACAATTT TACT (499) AGTT (500) 261 chr21: chr21: ACCTCGTCAGAA ACCTCGTCAGAA 0 48 5.61 2.38E−05 3′ss CLL 47970657- 47970657- ACAACCAGAGTT ACAACCAGAGGT 47971529 47971546 CCCCCGTTTCTA TGGACCAGCCTC GAGG (501) AATG (502) 262 chr22: chr22: TCATCCAGAGCC TCATCCAGAGCC 0 48 5.61 3.58E−03 3′ss CLL 50966161- 50966146- CAGAGCAGGGGA CAGAGCAGATGC 50966940 50966940 TGTCTGACCAGA AAGTGCTGCTGG TGCA (173) ACCA (174) 263 chr13: chr13: AAAGATTTCAGA AAAGATTTCAGA 0 39 5.32 1.50E−02 3′ss CLL 26970491- 26970491- AGAAATACTATT AGAAATACGTAT 26971275 26971289 TCTCTTTCAGGT ACCAACTGCAGC ATAC (503) CTTA (504) 264 chr5: chr5: CCAAAAGAGGGG CTCCATGCTCAG 0 39 5.32 4.28E−05 exon CLL 865696- 865696- ATAATGAGGGAA CTCTCTGGGGAA incl. 869359 870587 GGTGAAGAAGGA GGTGAAGAAGGA GCTG (505) GCTG (129) 265 chr22: chr22: CTCTCTCCAACC CTCTCTCCAACC 0 38 5.29 4.92E−04 3′ss CLL 39064137- 39064137- TGCATTCTCATC TGCATTCTTTGG 39066874 39066888 TCGCCCACAGTT ATCGATCAACCC GGAT (140) GGGA (141) 266 chr10: chr10: TCATCTTGAAAA TCATCTTGAAAA 0 34 5.13 3.62E−05 3′ss CLL 89519557- 89516679- ATGAAAATTCCT ATGAAAATGTGG 89527429 89527429 ATTTTACAGCTG ATAGGCATGTAG AGGA (506) ACCT (507) 267 chr20: chr20: TTTGCAGGGAAT TTTGCAGGGAAT 0 34 5.13 3.01E−05 3′ss CLL 35282126- 35282104- GGGCTACATCCC GGGCTACATACC 35284762 35284762 CTTGGTTCTCTG ATCTGCCAGCAT TTAC (35) GACT (36) 268 chr10: chr10: ACCCTGTCTACC ACCCTGTCTACC 1 64 5.02 4.28E−05 3′ss CLL 102276734- 102276717- AGCCTGTGTTTT AGCCTGTGGATA 102286155 102286155 CTGCCACCTACA GACCATGAAGCT GGAT (508) GAAG (509) 269 chr14: chr14: AGATGTCAGGTG AGATGTCAGGTG 1 62 4.98 8.04E−09 3′ss CLL 75356052- 75356052- GGAGAAAGCCTT GGAGAAAGCTGT 75356580 75356599 TGATTGTCTTTT TGGAGACACAGT CAGC (89) TGCA (90) 270 chr19: chr19: TGACACAGCCCT TGACACAGCCCT 1 59 4.91 4.19E−04 3′ss CLL 16264018- 16264018- GCAGGCAGGGTC GCAGGCAGAAGG 16265147 16265208 CGTGCAGGACCT ATCCCGCAAACG TTCC (510) TGGA (511) 271 chr7: chr7: GCGGGGCGAGGG GCGGGGCGAGGG 1 59 4.91 8.04E−09 3′ss CLL 102074108- 10207410S- CAGCTCCGCGTT CAGCTCCGGGAA 102076648 102076671 TCTCTGAATTCT GGAACGTCCCAG CCCC (512) GGAT (513) 272 chr1: chr1: TCTTTGGAAAAT TCTTTGGAAAAT 0 29 4.91 3.49E−03 3′ss CLL 1014583J0- 101458296- CTAATCAATTTT CTAATCAAGGGA 101460665 101460665 CTGCCTATAGGG AGGAAGATCTAT GAAG (25) GAAC (26) 273 ch17: chr7: CCACCTCACCAT CCACCTCACCAT 0 29 4.91 1.26E−02 3′ss CLL 99954506- 99954506- CACCCAGGGCAG CACCCAGGCCCT 99955849 99955842 CCCCTCCACAGG CAGGCAGCCCCT GCCC (514) CCAC (515) 274 chr19: chr19: GATGGTGGATGA GATGGTGGATGA 1 57 4.86 7.10E−04 3′ss CLL 23545541- 23545527- ACCCACAGTTTT ACCCACAGGTAT 23556543 23556543 TTTTTTTCAGGT ATGTCCTCATTT ATAT (11) TCCT (12) 275 chr3: chr3: GCCAACCTAGAG GCCAACCTAGAG 1 56 4.83 2.18E−05 3′ss CLL 108403188- 108403188- CCCCCCTGCTCT CCCCCCTGATGA 108405274 108405291 CTGCCTCTTACA CTGGCATAGCCT GATG (516) GGGC (517) 276 chr17: chr17: GGAGCAGTGCAG GGAGCAGTGCAG 0 27 4.81 1.14E−04 3′ss CLL 71198039- 71198039- TTGTGAAATCAT TTGTGAAAGTTT 71199162 71199138 TACTTCTAGATG TGATTCATGGAT ATGC (31) TCAC (32) 277 chr6: chr6: AACCGGGGGAGC AACCGGGGGAGC 0 27 4.81 8.95E−03 3′ss CLL 41040823- 41040823- GAGGCACGTTTC GAGGCACGGAGT 41046743 41046767 TTTCCCCACCTT GTACCTCACAGC TCTA (518) CTTC (519) 278 chr11: chr11: CACACAGACTGC CACACAGACTGC 1 54 4.78 3.38E−06 3′ss CLL 62376298- 62376277- GTTCGATGAGTG GTTCGATGCCTT 62376433 62376433 TCTTCCCCCTGC GCTGTTCACCCT CTTA (520) GATG (521) 279 chr14: chr14: AGTTAGAATCCA AGTTAGAATCCA 0 26 4.75 9.14E−07 3′ss CLL 74358911- 74358911- AACCAGAGTGTT AACCAGAGCTCC 74360478 74360499 GTCTTTTCTCCC TGGTACAGTTTG CCCA (61) TTCA (62) 280 chr11: chr11: CATAAAATTCTA CATAAAATTCTA 2 79 4.74 1.89E−06 3′ss CLL 4104212- 4104212- ACAGCTAATTCT ACAGCTAAGCAA 4104471 4104492 CTTTCCTCTGTC GCACTGAGCGAG TTCA (69) GTGA (70) 281 chr17: chr17: AGACCTACCAGA AGACCTACCAGA 0 25 4.70 1.18E−02 3′ss CLL 62574712- 62574694- AGGCTATGTGTT AGGCTATGAACA 62576906 62576906 TATTAATTTTAC GAGGACAACGCA AGAA (39) ACAA (40) 282 ch17: chr7: gtttttacctct GTTTTTACCTCT 1 49 4.64 1.80E−08 3′ss CLL 76943820- 76943806- GCCTCCTGATCT GCCTCCTGGTTT 76950041 76950041 CTCATCCTAGGT TCATACTCTGCA TTTC (522) CACC (523) 283 chr20: chr20: AGAACTGCACCT AGAACTGCACCT 0 24 4.64 3.30E−05 3′ss CLL 62701988- 62701988- ACACACAGCCCT ACACACAGGTGC 62703210 62703222 GTTCACAGGTGC AGACCCGCAGCT AGAC (29) CTGA (30) 284 chr3: chr3: CACTGCTGGGAG CACTGCTGGGAG 0 24 4.64 1.42E−07 3′ss CLL 129284872- 129284860- AGTGGAAGTTGC AGTGGAAGATTC 129285369 129285369 TTCCACAGATTC CTGAGAGCTGCC CTGA (524) GGCC (525) 285 chr11: chr11: GATTTTGGAGAG GATTTTGGAGAG 0 23 4.58 1.27E−04 3′ss CLL 33080641- 33080641- GCAACCAACTTT GCAACCAAATTC 33083060 33083075 GTTTTTCACAGA CCTGGACTTTGT TTCC (526) CACC (527) 286 chr1: chr1: TCACTCAAACAG TCACTCAAACAG 0 23 4.58 1.48E−03 3′ss CLL 179835004- 179834989- TAAACGAGTTTT TAAACGAGGTAT 179846373 179846373 ATCATTTACAGG GTGACGCATTCC TATG (53) CAGA (54) 287 chr2: chr2: TGCAGAACTGGA TGCAGAACTGGA 0 23 4.58 2.35E−02 3′ss CLL 23977668- 23977644- TAAAGAAGTGTA TAAAGAAGGTGC 23980287 23980287 TTTTTTTGTCTC TTCTAAAGTAAA AATT (528) GAAA (529) 288 chr5: chr5: ACTCTTATGCAG ACTCTTATGCAG 0 23 4.58 4.37E−03 3′ss CLL 1579622- 1581810- TCCCCATGAGGT TCCCCATGAGGA 1585098 1585098 TATGCTTATGTT GATCCTAGTCTC TCTC (530) ACCA (531) 289 chr6: chr6: AGTGTTTTACCA AGTGTTTTACCA 0 23 4.58 2.41E−04 3′ss CLL 30884736- 30884736- TGGATGTTGTCA TGGATGTTGGCT 30884871 30884881 TTCCAGGGCTCC CCTCAGTGGCTG TCAG (532) TGAC (533) 290 chr6: chr6: TTTATGATGCTG TTTATGATGCTG 0 23 4.58 1.66E−02 3′ss CLL 49416664- 49416640- CTTTAAAGTTTT CTTTAAAGCTCA 49419178 49419178 GTTAATGTTTTT TTAATGAAATTG CTTT (534) AAGA (535) 291 chr8: chr8: ATCTAAAAACAG ATCTAAAAACAG 0 23 4.58 3.15E−03 3′ss CLL 61741365- 61741365- AAGAGCAGGTCC AAGAGCAGGTGC 61742868 61742880 TTTTTTAGGTGC AAAAACTTCAAG AAAA (536) CTAT (537) 292 chr2: chr2: AGCAAGTAGAAG AGCAAGTAGAAG 2 68 4.52 3.76E−08 3′ss CLL 109102364- 109102364- TCTATAAAATTT TCTATAAAATAC 109102954 109102966 ACCCCCAGATAC AGCTGGCTGAAA AGCT (1) TAAC (2) 293 chr15: chr15: GGATTGCAGCCA GGATTGCAGCCA 0 22 4.52 5.30E−05 3′ss CLL 72859518- 72859518- ACACAAAGTTTC ACACAAAGGAAT 72862504 72862517 TCTTCATAGGAA GTCCCAAATGCC TGTC (538) ATGT (539) 294 chr5: chr5: GGTTTCGAGTTT GGTTTCGAGTTT 0 22 4.52 1.57E−02 3′ss CLL 109181707- 109181707- GAATAGTGTTTT GAATAGTGGTCA 109183328 109183357 GCTTGTTTGTTT GATTGAAGTTAT GTTT (540) CATG (541) 295 chr9: chr9: AAATGAAGAAAC AAATGAAGAAAC 0 22 4.52 5.36E−04 3′ss CLL 125759640- 125759640- TCCTAAAGCCTC TCCTAAAGATAA 125760854 125760875 TCTCTTTCTTTG AGTCCTGTTTAT TTTA (67) GACC (68) 296 chr11: chr11: GGATGACCGGGA GGATGACCGGGA 2 65 4.46 7.66E−06 3′ss CLL 71939542- 71939542- TGCCTCAGTCAC TGCCTCAGATGG 71939690 71939770 TTTACAGCTGCA GGAGGATGAGAA TCGT (47) GCCC (48) 297 chr11: chr11: CCACCGCCATCG CCACCGCCATCG 2 65 4.46 2.31E−08 3′ss CLL 64877395- 64877395- ACGTGCAGTACC ACGTGCAGGTGG 64877934 64877953 TCTTTTTACCAC GGCTCCTGTACG CAGG (167) AAGA (168) 298 chr19: chr19: TGCCTGTGGACA TGCCTGTGGACA 0 21 4.46 1.50E−04 3′ss CLL 14031735- 14031735- TCACCAAGCCTC TCACCAAGGTGC 14034130 14034145 GTCCTCCCCAGG CGCCTGCCCCTG TGCC (59) TCAA (60) 299 chr11: chr11: CGCAAGTACTTC CGCAAGTACTTC 0 20 4.39 2.24E−03 3′ss CLL 64676597- 64676622- CTGCCCCATCCA CTGCCCCAGGTA 64676742 64676742 GCAGCACACAGT GTGGTGACTGTG GGGA (542) AACC (543) 300 chr22: chr22: TTCATAACAAAC TCATCAATGCCC 0 20 4.39 1.08E−04 5′ss CLL 24210086- 24204389- CAGTAAATCACA CGACCTTGCACA 24210667 24210667 TTCAGGAATTCA TTCAGGAATTCA CCAA (544) CCAA (545) 301 chr2: chr2: AAATTTAACATT AAATTTAACATT 0 20 4.39 2.96E−02 3′ss CLL 24207701- 24207701- ACTCATAGTTTT ACTCATAGAGTA 24222524 24222541 TGCTGTTTTACA AGCCATATCAAA GAGT (546) GACT (547) 302 chr11: chr11: CACCGGGAGCTG CACCGGGAGCTG 2 59 4.32 8.17E−07 3′ss CLL 64119858- 64119858- CAGGGCCGCCCC CAGGGCCGGCAC 64120198 64120215 TTGTCCATCCCA GAGCAGCTGCAG GGCA (548) GCCC (549) 303 chr11: chr11: GGAGGTGGACCT GGAGGTGGACCT 0 19 4.32 5.52E−04 3′ss CLL 68363686- 68363686- GAGTGAACAATT GAGTGAACCACC 68367788 68367808 TCTCCCCTCTTT CAACTGGTCAGC TTAG (189) TAAC (190) 304 chr11: chr11: ATTGGACACAGA CTGTCTCTAGGC 0 19 4.32 5.03E−04 5′ss CLL 984190- 981299- GATGGGATATCG TAAGCAGAATCG 984644 984644 TGACGTCTGCAT TGACGTCTGCAT CCAC (550) CCAC (551) 305 chr17: chr17: GGGACCTCACCA GGGACCTCACCA 0 19 4.32 5.14E−03 3′ss CLL 43522984- 43523029- AGCGCCCGCCCC AGCGCCCGATCT 43527983 43527983 TCATCAACCTGC GCAGGCAGGCCC AGAT (552) TGAA (553) 306 chr9: chr9: CCAAGGACTGCA CCAAGGACTGCA 2 57 4.27 1.96E−04 3′ss CLL 139837449- 139837395- CTGTGAAGGCCC CTGTGAAGATCT 139837800 139837800 CCGCCCCGCGAC GGAGCAACGACC CTGG (175) TGAC (176) 307 chr4: chr4: GAGTGTGAATCA GAGTGTGAATCA 2 56 4.25 3.01E−02 3′ss CLL 56874548- 56874548- TCTGTGAATTTC TCTGTGAACCAG 56875878 56875900 ACATCACTCATT CTGAAAGAAACA TAAC (554) TTGG (555) 308 chr5: chr5: AGCATTGCTAGA AGCATTGCTAGA 1 37 4.25 3.83E−05 3′ss CLL 139815842- 139815842- AGCAGCAGCTTT AGCAGCAGGAAT 139818078 139818045 TGCAGATCCTGA TGGCAAATTGTC GGTA (19) AACT (20) 309 chr22: chr22: TCATCAATGCCC TCATCAATGCCC 0 18 4.25 3.60E−04 3′ss CLL 24204389- 24204389- CGACCTTGGTTC CGACCTTGCACA 24209938 24210667 ATGAACACATTG TTCAGGAATTCA AGGT (556) CCAA (545) 310 chr3: chr3: GCATTTCTGAGA GCATTTCTGAGA 0 18 4.25 3.30E−03 3′ss CLL 38038678- 38038678- AGGCTCGGGTCC AGGCTCGGGGGC 38038959 38038973 TCTCCCGCAGGG TGGCTTTGACCT GCTG (557) ACAG (558) 311 chr6: chr6: GCCAGTCCAGAG GCCAGTCCAGAG 1 36 4.21 6.38E−07 3′ss CLL 109767078- 109767065- CCCTCAAGTTCT CCCTCAAGCTCT 109767338 109767338 TCTTCTCAGCTC TGTGGCCATGGA TTGT (559) GAAG (560) 312 chr1: chr1: TGGCCGAGGCGC TGGCCGAGGCGC 2 54 4.20 1.35E−04 3′ss CLL 16803042- 16802999- TGACCAAGACCT TGACCAAGGCTG 16803424 16803424 TACTCAGGGGAT AGGGCAGAGGAG CCTC (561) GCCT (562) 313 chr2: chr2: TCTACTTGGTGG TCTACTTGGTGG 3 72 4.19 1.68E−04 3′ss CLL 103348885- 103348868- GCTTCTTGCATT GCTTCTTGGATT 103353104 103353104 TATTTTGTTTTA TGTTTGGTGTCA GGAT (563) GCAT (564) 314 chr14: chr14: GCTCCTGCTCAG GCTCCTGCTCAG 0 17 4.17 3.99E−04 3′ss CLL 78203438- 78203418- TATATCCGTTTT TATATCCGATAC 78205120 78205120 TATCTGCTTTCT ACACCATCTCAG TCAG (565) CAAG (566) 315 chr3: chr3: GAAATAGGGCAC GAAATAGGGCAC 0 17 4.17 7.71E−03 3′ss CLL 122152652- 122152635- AGATCCAGTTTT AGATCCAGACTG 122156016 122156016 TCTTTAATTTTA TGATAGATGCCA GACT (567) ACAT (568) 316 chr18: chr18: GCAACCTGTGTT GCAACCTGTGTT 1 33 4.09 3.11E−03 3′ss CLL 33724997- 33724997- TTACAAAGGTTT TTACAAAGATGG 33725896 33725910 TATTTTTTAGAT TGTCCTACAGCA GGTG (569) GCCA (570) 317 chr7: chr7: GTATCAAAGTGT GTATCAAAGTGT 1 33 4.09 4.37E−04 3′ss CLL 94157562- 94157562- GGACTGAGATTT GGACTGAGGATT 94162500 94162516 GTCTTCCTTTAG CCATTGCAAAGC GATT (27) CACA (28) 318 chr4: chr4: CCCCTGAAGTAC CCCCTGAAGTAC 0 16 4.09 1.12E−04 3′ss CLL 39868635- 39868617- TAGCAAAGCATG TAGCAAAGGTAC 39871013 39871013 TTAATATTTTAT AGGCAATTAAAC AGGT (571) TTCT (572) 319 chr10: chr10: GTTCCTCACTTT GTTCCTCACTTT 1 31 4.00 1.17E−04 3′ss CLL 99502921- 99502921- GAATGAGGTGTT GAATGAGGGTGC 99504468 99504485 TTTGATTCTGCA ATGGTACTCAGT GGTG (573) AGGT (574) 320 chr1: chr1: TCAGCCCTCTGA TCAGCCCTCTGA 0 15 4.00 6.99E−03 3′ss CLL 226036315- 226036255- ACTACAAAGGTG ACTACAAAACAG 226036597 226036597 TTTGTTCACAGA AAGAGCCTGCAA GATC (93) GTGA (94) 321 chr20: chr20: TCTTGGAAGGCA TCTTGGAAGGCA 0 15 4.00 4.25E−03 3′ss CLL 31983014- 31982922- GAGAAAAGATAT GAGAAAAGTCTA 31984566 31984566 TTCTAGAGCATT CCTCGAGACCTA TGGG (575) TGGC (576) 322 chr2: chr2: AACCCGGAGAGA AACCCGGAGAGA 0 15 4.00 5.64E−03 3′ss CLL 64456774- 64456774- AAAGGGAGTTTG AAAGGGAGCAAC 64456978 64478252 TTTTTAGGTCAG TGATGTTGCCAT AGTC (577) GCAG (578) 323 chr11: chr11: AATCTTCCCGAA AATCTTCCCCAA 1 30 3.95 7.37E−04 3′ss CLL 92887382- 92887443- GATGTATGTTCT GATGTATGGTTA 92895871 92895871 ATGTTCCAGCAG TATCAATCAGTG AGAT (579) AAAA (580) 324 chr18: chr18: CTCTCTTGTCAG CTCTCTTGTCAG 1 30 3.95 2.23E−02 3′ss CLL 43459192- 43459179- ACAAGCAGTTGT ACAAGCAGGTAA 43460039 43460039 CTCTTCCAGGTA TGGAGACTATAC ATGG (581) AGTG (582) 325 chr5: chr5: GCAGAGCTGTGG GCAGAGCTGTGG 1 30 3.95 1.23E−03 3′ss CLL 138724290- 138724274- CTTACCAGTCCC CTTACCAGATGT 138725368 138725368 TCCTTGTTCCAG GGCAAAATCTGG ATGT (583) CAAA (584) 326 chr17: chr17: TGCAGGAGACCG TGCAGGAGACCG 1 29 3.91 7.83E−03 3′ss CLL 58163509- 58163487- GCTTTTGGGTCC GCTTTTGGATAC 58165557 58165557 CCTTCTTATACC TGCTAATCAGTC CCTC (585) CTAG (586) 327 chr1: chr1: AGTTACAACGAA AGTTACAACGAA 1 29 3.91 2.95E−05 3′ss CLL 185056772- 185056772- CACCTCAGTGAC CACCTCAGGAGG 185060696 185060710 TCTTTTACAGGA CAATAACAGATG GGCA (162) GCTT (163) 328 chr10: chr10: TCTTGCCAGAGC TCTTGCCAGAGC 0 14 3.91 5.04E−05 3′ss CLL 99219232- 99219283- TGCCCACGCTCT TGCCCACGCTTC 99219415 99219415 CCACCCTCAGCT TTTCCTTGCTGC GCCT (587) TGGA (588) 329 chr4: chr4: CCATGGTCAAAA CCATGGTCAAAA 0 14 3.91 4.36E−02 3′ss CLL 152022314- 152022314- AATGGCAGCACC AATGGCAGACAA 152024139 152024022 AACAGGTCCGCC TGATTGAAGCTC AAAT (344) ACGT (345) 330 chr1: chr1: ATCAGAAATTCG ATCAGAAATTCG 3 57 3.86 4.89E−06 3′ss CLL 212515622- 212515622- TACAACAGGTTT TACAACAGCTCC 212519131 212519144 CTTTTAAAGCTC TGGAGCTTTTTG CTGG (65) ATAG (66) 331 chr1: chr1: GCAGGCTGCCCG GCAGGCTGCCCG 4 69 3.81 2.04E−07 3′ss CLL 156552962- 156552962- GGACTCTGGCTC GGACTCTGGGGA 156553113 156553129 TCTTTCTCTCAG CATGAAGGGACA GGGA (589) GTGG (590) 332 chr6: chr6: GCCAGTCCAGAG GCCAGTCCAGAG 2 41 3.81 4.40E−03 3′ss CLL 109767165- 109767065- CCCTCAAGTCTT CCCTCAAGCTCT 109767338 109767338 TACCAGACTTGC TGTGGCCATGGA AGGG (591) GAAG (560) 333 chr20: chr20: ACATGAAGGTGG ACATGAAGGTGG 5 81 3.77 1.48E−08 3′ss CLL 34144042- 34144042- ACGGAGAGGCTC ACGGAGAGGTAC 34144725 34144743 CCCTCCCACCCC TGAGGACAAATC AGGT (49) AGTT (50) 334 chr17: chr17: CTATTTCACTCT CTATTTCACTCT 1 25 3.70 2.79E−05 3′ss CLL 7131030- 7131102- CCCCCGAACCTA CCCCCGAAATGA 7131295 7131295 TCCAGGTTCCTC GCCCATCCAGCC CTCC (33) AATT (34) 335 ch16: ch16: TTCCCACTGGTC TTCCCACTGGTC 1 25 3.70 3.91E−03 3′ss CLL 110085185- 110085185- GCCTGCAGGTAT GCCTGCAGACTG 110086201 110086215 TTCTCTTTAGAC GCATCCTTCGAA TGGC (592) CCAA (593) 336 chr7: chr7: TGTAAATGGGGA TGTAAATGGGGA 1 25 3.70 2.18E−05 3′ss CLL 889240- 889240- AGCGCTGTTTTC AGCGCTGTGCGA 889468 889559 TACAGACTGCCA CGACTGTAAGGG TTGC (594) CAAG (595) 337 chr12: chr12: TCAATGCAAATA TCAATGCAAATA 0 12 3.70 1.92E−03 3′ss CLL 112915534- 112915534- TCATCATGGATT TCATCATGCCTG 112915638 112915660 TTCTTCCTAAAT AATTTGAAACCA TTCT (596) AGTG (597) 338 chr14: chrU: ACAAATCAACTG ACAAATCAACTG 0 12 3.70 1.38E−03 3′ss CLL 56100059- 56100059- GAAAGCAATTAC GAAAGCAAGCAG 56101230 56101243 TGTTTTCAGGCA TCTGCAGAACTA GTCT (598) AATA (599) 339 chr17: chr17: CAAAGCGCCCAG CAAAGCGCCCAG 0 12 3.70 2.10E−02 3′ss CLL 2266428- 2266428- CCCTGGGGGCTG CCCTGGGGATCC 2266727 2266758 GAGGCTGAGCCC GGAAACGGCACT CGGC (600) CAAG (601) 340 chr19: chr19: TGACACAGCCCT TGACACAGCCCT 0 12 3.70 4.53E−05 3′ss CLL 16264018- 16264018- GCAGGCAGGACC GCAGGCAGAAGG 16265158 16265208 TTTCCCCCTCCC ATCCCGCAAACG TAGT (602) TGGA (511) 341 chr1: chr1: AGTTGCCATTCC AGTTGCCATTCC 0 12 3.70 4.52E−03 3′ss CLL 186324917- 186324900- ATTACATGTCTT ATTACATGCTTC 186325417 186325417 TACTTTCCTGAA AAGCTTAGATGA GCTT (603) TGTT (604) 342 chr3: chr3: ACTGATTAAAAA ACTGATTAAAAA 4 62 3.66 9.33E−05 3′ss CLL 56649300- 56649300- TCTTGGTGGTGA TCTTGGTGTTGA 56649931 56649949 TTTCTCTTTGCC TACAATACAAAT AGTT (605) GGAA (606) 343 chr6: chr6: CCGGGGCCTTCG CCGGGGCCTTCG 4 58 3.56 3.53E−06 3′ss CLL 10723474- 10723474- TGAGACCGCTTG TGAGACCGGTGC 10724788 10724802 TTTTCTGCAGGT AGGCCTGGGGTA GCAG (95) GTCT (96) 344 chr3: chr3: AGGCTATTGTTG AGGCTATTGTTG 1 22 3.52 2.36E−03 3′ss CLL 184587316- 184587316- CAGACCGGGCTG CAGACCGGATGG 184588487 184588503 TTTTCCTTACAG TAGAAATCCTAT ATGG (607) TCCA (608) 345 chr4: chr4: CCTTTCAAGAAA CCTTTCAAGAAA 1 22 3.52 1.60E−02 3′ss CLL 3124663- 3124663- ACAAAAAGTCGC ACAAAAAGGCAA 3125976 3127275 TTTTTCCAGTGG AGTGCTCTTAGG CGGT (609) AGAA (610) 346 chr9: chr9: ACACGGAGCTCA ACACGGAGCTCA 2 33 3.50 1.45E−05 3′ss CLL 123933826- 123933826- AGAAACAGTTTC AGAAACAGATGG 123935634 123935520 TTCCAGAACTAC CAAACCAAAAAG CAGC (611) ATTT (612) 347 chr19: chr19: CAAGCAGGTCCA CAAGCAGGTCCA 6 76 3.46 9.28E−05 3′ss CLL 5595521- 5595508- AAGAGAGATTTT AAGAGAGAAGCT 5598803 5598803 GGTAAACAGAGC CCAAGAGTCAGG TCCA (138) ATCG (139) 348 chr5: chr5: GACTTCGAACAT GACTTCGAACAT 4 54 3.46 7.66E−03 3′ss CLL 78608321- 78608321- TTAAACAGTGTG TTAAACAGAGGT 78610192 78610079 TTACAGGTAGAA ATCCTGGGCAAG GAGA (613) TCAT (614) 349 chr2: chr2: ACCACGAAGGGT ACCACGAAGGGT 2 32 3.46 1.25E−02 3′ss CLL 231050873- 231050859- CACACAAGTCTA CACACAAGGGGC 231065600 231065600 TTTGGTCCAGGG AGCCTCACCTGG GCAG (615) GCAT (616) 350 chr1: chr1: CGATCTCCCAAA CGATCTCCCAAA 1 21 3.46 1.57E−05 3′ss CLL 52880319- 52880319- AGGAGAAGTCTG AGGAGAAGCCCC 52880412 52880433 ACCAGTCTTTTC TCCCCTCGCCGA TACA(55) GAAA{56) 351 chr2: chr2: TTAACAAACACG TGCTGGCACACC 0 10 3.46 8.22E−03 5′ss CLL 69015785- 69015088- TGAATCTACAGT CTGTGGAGCAGT 69034404 69034404 GTTTGGCCAGCG GTTTGGCCAGCG CTTG{617) CTTG{618) 352 chr5: chr5: CGCCCCAGGGCA CGCCCCAGGGCA 0 10 3.46 1.97E−03 3′ss CLL 156915521- 156915497- AGCGAAAGGTGT AGCGAAAGGTGA 156916109 156916109 TCCTTGACTTGT TCAACACTCCGG GCGT(619) AAAT{620) 353 chr9: chr9: TGGTACAACTTC TGGTACAACTTC 0 10 3.46 6.70E−03 3′ss CLL 115934002- 115933986- AGGAAAAGTCTG AGGAAAAGTGTT 115935732 115935732 TTTGTTTTGCAG TAGCCCTCCAGG TGTT{621) CCCA{622) 354 chr14: chr14: TGGATTTGCTCG TGGATTTGCTCG 1 20 3.39 1.52E−04 3′ss CLL 50808004- 50807950- gcttttgatttt GCTTTTGACTGG 50808849 50808849 GATTCCAGCCTT ACCGAGTGACTA CCGC{623) CTAT{624) 355 chr18: chr18: GATGAGGACCCC GATGAGGACCCC 5 61 3.37 3.06E−06 3′ss CLL 9133520- 9133508- CACATAGGTTTC CACATAGGGATG 9136361 9136361 CAAACCAGGATG GCCATAGCAGCC GCCA{625) ACAA{626) 356 chr10: chr10: TACCTCTGGTTC TACCTCTGGTTC 3 39 3.32 2.21E−05 3′ss CLL 99214556- 99214556- CTGTGCAGTCTT CTGTGCAGTTCT 99215395 99215416 CGCCCCTCTTTT GTGGCACTTGCC CTTA{13) CTGG{14) 357 chr2: chr2: TGTTTTAAATTC TGTTTTAAATTC 2 29 3.32 8.44E−06 3′ss CLL 225670231- 225670246- CATAGCAGCTAT CATAGCAGCATT 225670842 225670842 TTCTACAGTAAA TTCATCAATAGC CCAT{627) TATT{628) 358 chrX: chrX: GCTGGGATGTTA GCTGGGATGTTA 1 19 3.32 2.06E−02 3′ss CLL 153323986- 153298008- GGGCTCAGCCTG GGGCTCAGGGAA 153357641 153357641 TCGTTCCAGGAC GAAAAGTCAGAA CCAG{629) GACC{630) 359 chr16: chr16: CTGGTTATTGCA CTGGTTATTGCA 0 9 3.32 6.10E−05 3′ss CLL 72139523- 72139523- AATTAAAGCTCT AATTAAAGGTCT 72139882 72139903 TTGCCGTCCCCT TCAACCCCAGGA CCTA{631) TTGG{632) 360 chr5: chr5: CTCCATGCTCAG CTCCATGCTCAG 4 48 3.29 1.01E−06 exon CLL 869519- 865696- CTCTCTGGTTTC CTCTCTGGGGAA incl. 870587 870587 TTTCAGGGCCTG GGTGAAGAAGGA CCAT{128) GCTG{129) 361 chrX: chrX: GGTCATGCTAAT GGTCATGCTAAT 8 82 3.21 5.22E−07 3′ss CLL 70516897- 70516897- GAGACAGGTCTG GAGACAGGATTT 70517210 70517226 TTGTTTTTTTAG GATGAGGCGCCA ATTT{633) AGAA{634) 362 chr16: chr16: GTCAGCATTTGC GTCAGCATTTGC 2 26 3.17 7.43E−04 3′ss CLL 47347747- 47347734- AGACTTTGTTTC AGACTTTGATGG 47399698 47399698 TTTTGGCAGATG AGATGGACACAT GAGA{635) GGAT{636) 363 chr5: chr5: GCAGAGCTGTGG GCAGAGCTGTGG 2 26 3.17 1.17E−03 3′ss CLL 138725125- 138724274- CTTACCAGACTT CTTACCAGATGT 138725368 138725368 CTCCCTTTCCAG GGCAAAATCTGG GCCC{637) CAAA{584) 364 chr11: chr11: CGGCGCGGGCAA CGGCGCGGGCAA 0 8 3.17 6.70E−03 3′ss CLL 62648919- 62648919- CCTGGCGGCCCC CCTGGCGGGTCT 62649352 62649364 CATTTCAGGTCT GAAGGGGCGTCT GAAG (165) CGAT (166) 365 chr11: chr11: TGCAGCTGGCCC TGCAGCTGGCCC 0 8 3.17 2.22E−02 3′ss CLL 64002365- 64002365- CCGCCCAGGTCT CCGCCCAGGCCC 64002911 64002929 TTTCTCTCCCAC CTGTCTCCCAGC AGGC (638) CTGA (639) 366 chr14: chrU: CACAGCAAGCAC CACAGCAAGCAC 0 8 3.17 3.01E−05 3′ss CLL 31169464- 31169464- CTTCTGAGTTCT CTTCTGAGGCTG 31171484 31171501 TTTCTTATTTCA ATTTGGAGCAAT GGCT (640) ATAA (641) 367 chr1: chr1: TCACACCTGTAG TCACACCTGTAG 0 8 3.17 9.33E−05 3′ss CLL 186300728- 186300711- GAACTGAGTGTA GAACTGAGGAAG 186301326 186301326 TTATGATACAGG AAGTTATGGCAG AAGA (642) AAGA (643) 368 chr5: chr5: AAAATTGACTAT AAAATTGACTAT 0 8 3.17 7.30E−03 3′ss CLL 169101449- 169101449- GGCAACAATTTT GGCAACAAAATC 169108733 169108747 TGCTTTACAGAA CTTGAGCTTGAT TCCT (644) TTGA (645) 369 chr9: chr9: ACACGGAGCTCA ACACGGAGCTCA 0 8 3.17 5.42E−04 3′ss CLL 123933826- 123933826- AGAAACAGAACT AGAAACAGATGG 123935644 123935520 ACCAGCAGATCT CAAACCAAAAAG AGAA (646) ATTT (612) 370 chr10: chr10: GGGAGGAAAAGT GGGAGGAAAAGT 5 52 3.14 1.27E−03 3′ss CLL 112058568- 112058548- AATTAATGTTTT AATTAATGGAAG 112060304 112060304 TGTTTTTCTTTT TTATAGAACTAA TTAG (647) CCAA (648) 371 chr3: chr3: ATTTGGATCCTG ATTTGGATCCTG 4 43 3.14 1.46E−04 3′ss CLL 196792335- 196792319- TGTTCCTCTTTT TGTTCCTCATAC 196792578 196792578 TTTCTGTTAAAG AACTAGACCAAA ATAC (87) ACGA (88) 372 chr12: chr12: ATTTGGACTCGC ATTTGGACTCGC 3 34 3.13 1.20E−04 3′ss CLL 105601825- 105601807- TAGCAATGATGT TAGCAATGAGCA 105601935 105601935 CTGTTTATTTTT TGACCTCTCAAT AGAG (41) GGCA (42) 373 chr19: chr19: CTATGGGCTCAC CTATGGGCTCAC 7 67 3.09 2.90E−04 3′ss CLL 41084118- 41084118- TCCTCTGGTCCT TCCTCTGGTTCG 41084353 41084367 CCTGTTGCAGTT TCGCCTGCAGCT CGTC (169) TCGA (170) 374 chr11: chr11: TTCTCCAGGACC TTCTCCAGGACC 1 16 3.09 4.69E−03 3′ss CLL 125442465- 125442465- TTGCCAGACCTT TTGCCAGAGGAA 125445146 125445158 TTCTATAGGGAA TCAAAGACTCCA TCAA (150) TCTG (151) 375 chr12: chr12: AGAAGGAGCTGC AGAAGGAGCTGC 1 16 3.09 2.88E−03 3′ss CLL 110437589- 110437589- AGGGCCAGTGTT AGGGCCAGAATG 110449795 110449809 TCCTTCACAGAA TGGAGGCTGTGG TGTG (649) ACCC (650) 376 chr8: chr8: GCTCTGGAGAAT GCTCTGGAGAAT 4 41 3.07 6.90E−07 3′ss CLL 126051218- 126051201- CTCAATAAGGTT CTCAATAAGGCT 126052036 126052036 TTTCTTCCTTTA CTCCTAGCAGAC GGGC (651) ATTG (652) 377 chr3: chr3: CATGCAATGAAC CATGCAATGAAC 2 24 3.06 7.00E−06 3′ss CLL 42674315- 42674315- CCAAAAGGTTGA CCAAAAGGTCAC 42675109 42675071 TTCCAGTGCTAA TCTGAGAGGAGT AAGG (653) GATA (654) 378 chr5: chr5: TGCTTCCGGAAC TGCTTCCGGAAC 6 57 3.05 3.26E−05 3′ss CLL 139941307- 139941286- AGTGACAGCCCC AGTGACAGGGAC 139941428 139941428 ATCTCTGCCCCT TTCGCTTTTGTG GCTA (655) GCAA (656) 379 chr12: chr12: TGGGTTTCAGCA TGGGTTTCAGCA 0 7 3.00 4.31E−03 3′ss CLL 64199184- 64199184- AGAGAACATTGT AGAGAACACTGG 64202434 64202454 TTTTCTGATTTT CAGCCTCAGGAA CTAG (657) ACAA (658) 380 chr18: chr18: AGGACATGGATT AGGACATGGATT 0 7 3.00 4.13E−03 3′ss CLL 47311742- 47311721- TGGTAGAGTGCT TGGTAGAGGTGA 47313660 47313660 CTAATTTTTGTT ATGAAGCTTTTG TTAA (659) CTCC (660) 381 chr19: chr19: ATCACAACCGGA ATCACAACCGGA 0 7 3.00 2.46E−02 3′ss CLL 15491444- 15491423- ACCGCAGGCTCC ACCGCAGGCTCA 15507960 15507960 TTCTGCCCTGCC TGATGGAGCAGT CGCA (661) CCAA (662) 382 chr1: chr1: CAGGAAGCAGCT CAGGAAGCAGCT 0 7 3.00 7.09E−04 3′ss CLL 46068037- 46068037- agtcttttatgt AGTCTTTTAGGT 46070588 46070607 TTATTCTCTTTG AAGAAGTATGGA TAGA (663) GAGA (664) 383 chr21: chr21: GAACCAATGGAA GAACCAATGGAA 0 7 3.00 1.40E−02 3′ss CLL 45452053- 45452053- TGGAGAAGGCAC TGGAGAAGGTCC 45452682 45457672 AGGCGTTTTGCA TATGGCCGGGCT AAGG (665) CCGA (666) 384 chr2: chr2: TGCTTGTAAAAT TGCTTGTAAAAT 0 7 3.00 1.13E−02 3′ss CLL 160673561- 160673543- TGAAATGGTGCT TGAAATGGTTGA 160676236 160676236 TTTAATTATTAT CTACAAAGAAGA AGTT (667) ATAT (668) 385 chr5: chr5: ACTCGCGCCTCT ACTCGCGCCTCT 0 7 3.00 4.59E−02 3′ss CLL 150411955- 150411944- TCCATCTGTTTT TCCATCTGCCGG 150413168 150413168 GTCGCAGCCGGA AATACACCTGGC ATAC (109) GTCT (110) 386 ch17: chr7: CCACCTCACCAT CCACCTCACCAT 0 7 3.00 2.08E−02 3′ss CLL 99954506- 99954506- CACCCAGGCCCC CACCCAGGCCCT 99955853 99955842 TCCACAGGGCCC CAGGCAGCCCCT CTCT (669) CCAC (515) 387 chr4: chr4: CGTCTCCATGAC CGTCTCCATGAC 6 54 2.97 7.33E−05 3′ss CLL 995351- 995351- CATGCAAGGTGT CATGCAAGGCTT 995438 995466 AGACGCAGTGCT CCTGAACTACTA CCCC (670) CGAT (671) 388 chr15: chr15: AGGAGGCAATTA AGGAGGCAATTA 8 68 2.94 1.81E−04 3′ss CLL 75131104- 75131086- AGGCAAAGGCCC AGGCAAAGGTGG 75131350 75131350 TTTCCCTGCTAC GGCAGTACGTGT AGGT (672) CCCG (673) 389 chrX: chrX: TACAAGAGCTGG TACAAGAGCTGG 2 22 2.94 1.26E−04 3′ss CLL 153699660- 153699660- GTGGAGAGGGTC GTGGAGAGGTAT 153699819 153699830 CCAACAGGTATT TATCGAGACATT ATCG (158) GCAA (159) 390 chr9: chr9: CACCACGCCGAG CACCACGCCGAG 5 43 2.87 3.76E−08 3′ss CLL 125023777- 125023787- GCCACGAGACAT GCCACGAGTATT 125026993 125026993 TGATGGAAGCAG TCATAGACATTG AAAC (142) ATGG (143) 391 chr14: chr14: TTACCTCCGAAG TTACCTCCGAAG 10 79 2.86 3.40E−05 3′ss CLL 23242937- 23242925- GATCGTGGTTCT GATCGTGGGGTC CTTTGTAGGGTC TGCCACAAGGTA 23243141 23243141 TGCC (674) CCTC (675) 392 chr11: chr11: AATAAGCCCTCA AATAAGCCCTCA 0 6 2.81 1.66E−02 3′ss CLL 67376193- 67376193- GATGGCAGCCTG GATGGCAGGCCC 67376896 67376922 TCTGACCTGTGG AAGTATCTGGTG GCCC(676) GTGA{677) 393 chr16: chr16: ACTCCCAGCTCA ACTCCCAGCTCA 0 6 2.81 1.49E−02 3′ss CLL 56403209- 56403239- ATGCAATGGTTC ATGCAATGGCTC 56419830 56419830 CATACCATCTGG ATCAGATTCAAG TACT{332) AGAT{333) 394 chr17: chr17: GCCTGGACCTGT GCCTGGACCTGT 0 6 2.81 4.26E−02 3′ss CLL 43316432- 43316432- ACTTGGAGGTGC ACTTGGAGAGGC 43317875 43317842 AGATCCAGGCGT TTCGGCTCACCG ACCT(678) AGAG{679) 395 chr21: chr21: CTGTAACTACTA CTGTAACTACTA 0 6 2.81 3.47E−04 3′ss CLL 47655360- 47655340- GCCCACAGTTTC GCCCACAGAGTG 47656742 47656742 TTTTTTATTCAA ACATGATGAGGG ATAG{680) AGCA{681) 396 chr3: chr3: CTCTCAATGCAG CTCTCAATGCAG 0 6 2.81 1.49E−03 3′ss CLL 71019345- 71015207- CTTTACAGTTTT CTTTACAGGCTT 71019886 71019886 CCTGCAGATTGT CAATGGCTGAGA TCAA{682) ATAG{683) 397 chr9: chr9: GGAGCAGTTCCA GGAGCAGTTCCA 0 6 2.81 4.44E−03 3′ss CLL 95007367- 95007353- GAAGACTGCTGC GAAGACTGGGAC 95009658 95009658 TTCTCCATAGGG CATTGTTGTGGA ACCA{684) AGGC{685) 398 chrX: chrX: CCTGCTGGACCA CCTGCTGGACCA 0 6 2.81 1.25E−02 3′ss CLL 48340103- 48340103- TTCTTACGTTGT TTCTTACGATTT 48340769 48340796 CTCCCCCTGTTC CAACCAGCTGGA CTAA{686) TGGT{687) 399 chr20: chr20: GGATTTTGATAA GGATTTTGATAA 7 53 2.75 1.01E−03 3′ss CLL 36631195- 36631178- TGAAGAAGTTGT TGAAGAAGAGGA 36634598 36634598 GCTCTTTTTCCA ACAGTCAGTCCC GAGG{688) TCCC{689) 400 chr4: chr4: CGTCTCCATGAC CGTCTCCATGAC 3 26 2.75 5.89E−04 3′ss CLL 995351- 995351- CATGCAAGGGCA CATGCAAGGCTT 995433 995466 GGTGTAGACGCA CCTGTAACTACTA GTGC{690) CGAT{671) 401 chr15: chr15: TGATTCCAAGCA TGATTCCAAGCA 2 19 2.74 3.63E−05 3′ss CLL 25213229- 25213229- AAAACCAGCCTT AAAACCAGGCTC 25219533 25219457 CCCCTAGGTCTT CATCTACTCTTT CAGA{230) GAAG{231) 402 chr18: chr18: AGTGCCAGCTGC AGTGCCAGCTGC 2 19 2.74 1.04E−03 exon CLL 47811617- 47811721- GGGCCCGGCTCT GGGCCCGGGAAT skip 47812118 47812118 CACCAGTGACGC CGTACAAGTACT CCTC{691) TCCC{692) 403 chr18: chr18: AACTTACTTTGT AACTTACTTTGT 2 19 2.74 1.46E−04 3′ss CLL 66356291- 66355002- TTATGATGCTTT TTATGATGAGTA 66358531 66358531 TATTTTAGATTC TGAAGATGGTGA AGAG{693) TCTG{694) 404 chr21: chr21: ATCATAGCCCAC ATCATAGCCCAC 3 25 2.7 2.17E−02 3′ss CLL 37416267- 37416254- ATGTCCAGTTTT ATGTCCAGGTAA 37417879 37417879 TCTTTCTAGGTA AAGCAGCGTTTA AAAG{695) ATGA{696) 405 chrX: chrX: TGACTCCGCTGC TGACTCCGCTGC 1 12 2.7 2.07E−02 3′ss CLL 118923962- 118923974- TCGCCATGACTT TCGCCATGTCTT 118925536 118925536 TCAGGATTAAGC CTCACAAGACTT GATT{697) TCAG{698) 406 chr1: chr1: CCAAGCACCTGA CCAAGCACCTGA 7 50 2.67 1.87E−03 3′ss CLL 100606070- 100606070- AACAGCAGTTTG AACAGCAGATGC 100606400 100606522 CAGGCTTCTATT TGAAAAAGTTCA TTAG (699) CTTC (700) 407 chr12: chr12: GCCTGCCTTTGA GCCTGCCTTTGA 13 88 2.67 1.74E−07 3′ss CLL 113346629- 113346629- TGCCCTGGATTT TGCCCTGGGTCA 113348840 113348855 TGCCCGAACAGG GTTGACTGGCGG TCAG (71) CTAT (72) 408 ch17: chr7: CGAGCTGTTGGC CGAGCTGTTGGC 7 49 2.64 2.27E−05 3′ss CLL 149547427- 149547427- ATCCTTGGTTTC ATCCTTGGGACC 149549949 149556510 TTGTCCACAGGA TGCCGCTGCCAA GAAG (701) GCCA (702) 409 chr11: chr11: GCTTTCTACGGA GCTTTCTACGGA 3 24 2.64 1.08E−04 3′ss CLL 126142974- 126142974- ACATCAATGAGC ACATCAATGAGT 126143210 126143230 TTCTGTCTGCAC ACCTGGCCGTAG ACAG (703) TCGA (704) 410 chr8: chr8: TTATTTTACACA TTATTTTACACA 3 24 2.64 2.89E−05 3′ss CLL 38095145- 38095145- ATCCAAAGCCAG ATCCAAAGCTTA 38095624 38095606 TTGCAGGGTCTG TGGTGCATTACC ATGA (57) AGCC (58) 411 chr12: chr12: CAGGAATACCTG CAGGAATACCTG 1 11 2.58 2.06E−06 3′ss CLL 62783294- 62783294- CAGATAAGATTT CAGATAAGATGA 62783413 62783384 CACAGAATATTC TAGTTACTGATA GCTA (705) TATA (706) 412 chr17: chr17: CTACACCAAGAA CTACACCAAGAA 1 11 2.58 2.56E−03 3′ss CLL 18007203- 18007203- GAGAGGACCTCT GAGAGGACAGAG 18007857 18007936 TCCCTCGCGCAG GCCAGACTTCAC AATC (707) AGAC (708) 413 chr17: chr17: CGGAGGCTGTCT CGGAGGCTGTCT 1 11 2.58 4.39E−03 3′ss CLL 73486839- 73486839- CCTCTCAGACTT CCTCTCAGGAAA 73487110 73487129 CCTCTCTCCCAC TGCTGCGCTGCA CAGG (709) TTTG (710) 414 chr11: chr11: TCCTGCTGGAGC TCCTGCTGGAGC 0 5 2.58 5.77E−03 3′ss CLL 68331900- 68331900- CACCCAAGCTTT CACCCAAGAAAA 68334466 68334481 TTCTTCTTCAGA GTGTGATGAAGA AAAG (711) CCAC (712) 415 chr13: chr13: AGCTGAAATTTC AGCTGAAATTTC 0 5 2.58 3.85E−02 3′ss CLL 113915073- 113915073- CAGTAAAGGGGG CAGTAAAGCCTG 113917776 113917800 gttttattcttc GAGATTTGAAAA TTTT (152) AGAG (153) 416 chr13: chr13: ACCAAGCATACT ACCAAGCATACT 0 5 2.58 1.04E−02 3′ss CLL 20656270- 20656270- TCCAGATGTTCT TCCAGATGGGTC 20656905 20656920 CTCTATTTAAGG AATATTCTCTCG GTCA (713) AGTT (714) 417 chr19: chr19: CGGGCCGCCCCC CGGGCCGCCCCC 0 5 2.58 1.76E−03 3′ss CLL 36231397- 36230989- CTGCCCGGTGTT CTGCCCGGAGGC 36231924 36231924 CTTCTGGGCAGT CGGTCCCTGCCA GCAA (715) AGGG (716) 418 chr20: chr20: ACATGAAGGTGG ACATGAAGGTGG 0 5 2.58 3.36E−03 3′ss CLL 34144042- 34144042- ACGGAGAGTTCT ACGGAGAGGTAC 34144761 34144743 CTGTGACCAGAC TGAGGACAAATC ATGA (250) AGTT (50) 419 chr21: chr21: AAGATGTCCCTG AAGATGTCCCTG 0 5 2.58 3.03E−02 3′ss CLL 38570326- 38570326- TGAGGATTGTGT TGAGGATTGCAC 38572514 38572532 GTTTGTTTCCAC TGGGTGCAAGTT AGGC (224) CCTG (225) 420 chr6: chr6: GGAGGACTGGGG GGAGGACTGGGG 0 5 2.58 2.97E−03 3′ss CLL 32095539- 32095527- TCTGCAGACATT TCTGCAGAACAG 32095893 32095893 TCTTGCAGACAG CACCTTGTATTC CACC (717) TGGC (718) CTGCCCCCTGCG CTGCCCCCTGCG 0 5 2.58 7.48E−03 3′ss CLL 421 chr7: chr7: CCACACGGCCTC CCACACGGTGAT 44795898- 44795898- TTTCCCTGCAGT GGTTCATTCGCA 44796008 44796023 GATG (719) TATG (720) TGTAAATGGGGA TGTAAATGGGGA 0 5 2.58 2.68E−02 3′ss CLL 422 chr7: chr7: AGCGCTGTACTG AGCGCTGTGCGA 889240- 889240- CCATTGCTATGC CGACTGTAAGGG 889477 889559 ACGG (721) CAAG (595) GGCCAGCCCCCT GGCCAGCCCCCT 10 62 2.52 1.37E−08 3′ss CLL 423 chr12: chr12: TCTCCACGGCCT TCTCCACGGTAA 120934019- 120934019- TGCCCACTAGGT CCATGTGCGACC 120934204 120934218 AACC (206) GAAA (207) CTGATGAAAACT CTGATGAAAACT 11 66 2.48 1.51E−04 3′ss CLL 424 chr9: chr9: ACTACAAGCAGA ACTACAAGGCCC 93641235- 93641235- CACCTTACAGGC AGACCCATGGAA 93648124 93650030 CAGG (722) AGTG (723) TTCAGCTGCCCC TTCAGCTGCCCC 8 49 2.47 1.42E−05 3′ss CLL 425 chr17: chr17: TGAAGAAGAAAC TGAAGAAGGAAT 57079102- 57079075- ATGTTCTCCTTC GAGTAGCGACAG 57089688 57089688 CTTC (724) TGAC (725) GAAACCAACTAA GAAACCAACTAA 3 21 2.46 9.18E−03 3′ss CLL 426 chr15: chr15: AGGCAAAGCCCA AGGCAAAGGTAA 59209219- 59209198- TTTTCCTTCTTT AAAACATGAAGC 59224554 59224554 CGCA (101) AGAT (102) TCCCGAAGCCAC TCCCGAAGCCAC 3 21 2.46 4.67E−04 3′ss CLL 427 chr7: chr7: CTCATGAGCCTC CTCATGAGGTCG 99752804- 99752787- TGCCTTCCCCCA GGCAGTGTGATG 99752884 99752884 GGTC (726) GAGC (727) CCCCGGTGCGTA CCCCGGTGCGTA 1 10 2.46 2.22E−02 3′ss CLL 428 chr8: chr8: AGGAGGAGCCTG AGGAGGAGGAGG 145624052- 145624028- CCCCCCTTTGGC ACAATCCCAAGG 145624168 145624168 CCTG (728) GGGA (729) AGCTGGAGAAAA AGCTGGAGAAAA 1 10 2.46 3.34E−04 3′ss CLL 429 chr9: chr9: ACCTTCTTTTTC ACCTTCTTATGG 123932094- 123932094- TTCCAGAACTAC CAAACCAAAAAG 123935634 123935520 CAGC (730) ATTT (731) TTCGTTGGCAGC TTCGTTGGCAGC 6 37 2.44 2.59E−04 3′ss CLL 430 chr15: chr15: TTCTGCTGAGAC TTCTGCTGCGTC 77327904- 77327904- CCTGACCCCCAC CACAGAGACCCT 77328151 77328142 CCCC (732) GACC (733) GTGCTTGGAGCC GTGCTTGGAGCC 5 31 2.42 4.69E−03 3′ss CLL 431 chr19: chr19: CTGTGCAGACTT CTGTGCAGCCTG 55776746- 55776757- TCCGCAGGGTGT GTGACAGACTTT 55777253 55777253 GCGC (179) CCGC (180) GTGCCAACGAGG GTGCCAACGAGG 10 57 2.4 1.64E−03 3′ss CLL 432 chr4: chr4: ACCAGGAGTTCT ACCAGGAGATGG 184577127- 184577114- TTATTTCAGATG AACTAGAAGCAT 184580081 184580081 GAAC (734) TACG (735) CCTCACGATGCA CCTCACGATGCA 7 40 2.36 8.53E−04 3′ss CLL 433 chr16: chr16: AGGCCACGAGTT AGGCCACGGGAG 67692735- 67692719- CATGTCCCACAG AAGCTGTGTACA 67692830 67692830 GGAG (736) CTGT (737) 434 chr6: chr6: AGGGGGCTCTTT AGGGGGCTCTTT 14 75 2.34 3.51E−06 3′ss CLL 91269953- 91269933- ATATAATGTTTG ATATAATGTGCT 91271340 91271340 TGCCTTTCTTTC GCATGGTGCTGA GCAG (265) ACCA (266) 435 chr15: chr15: TCACACAGGATA GCCTCACTGAGC 2 14 2.32 4.92E−03 exon CLL 25212299- 25207356- ATTTGAAAGTGT AACCAAGAGTGT incl. 25213078 25213078 CAGTTGTACCCG CAGTTGTACCCG AGGC (164) AGGC (145) 436 chr9: chr9: AAAAATAAAGCC CTGATGAAAACT 1 9 2.32 3.99E−03 5′ss CLL 93648256- 93641235- TTTCCCAGGCCC ACTACAAGGCCC 93650030 93650030 AGACCCATGGAA AGACCCATGGAA AGTG (738) AGTG (723) 437 chr14: chr14: CGAGGATGAAGA CGAGGATGAAGA 0 4 2.32 4.50E−03 3′ss CLL 34998676- 34998681- CAGAGCAGGTGA CAGAGCAGTACA 35002649 35002649 CCAAGAAAAAAA GGTGACCAAGAA AGAA (739) AAAA (740) 438 chr2: chr2: AGACAAGGGATT AGACAAGGGATT 0 4 2.32 1.21E−02 3′ss CLL 26437445- 26437430- GGTGGAAACATT GGTGGAAAAATT 26437921 26437921 TTATTTTACAGA GACAGCGTATGC ATTG (295) CATG (296) 439 chrX: chrX: AAAAGAAACTGA AAAAGAAACTGA 16 82 2.29 2.84E−08 3′ss CLL 129771378- 129771384- GGAATCAGTATC GGAATCAGCCTT 129790554 129790554 ACAGGCAGAAGC AGTATCACAGGC TCTG (303) AGAA (304) 440 chr1: chr1: TTCCCCATCAAC TTCCCCATCAAC 5 28 2.27 4.85E−06 3′ss CLL 19480448- 19480433- ATCAAAAGTTTT ATCAAAAGTTCC 19481411 19481411 GTTGTCTGCAGT AATGGTGGCAGT TCCA (202) AAGA (203) 441 chr3: chr3: AAAATGGGCTCA AAAATGGGCTCA 10 52 2.27 1.39E−04 3′ss CLL 141896447- 141896418- GCAGTTAGGGTT GCAGTTAGACCT 141900302 141900302 TTTTGTTGTTTG TTTCACAGATGC TTTG (741) TGCT (742) 442 chr1: chr1: AAGCACTGGCCC AAGCACTGGCCC 4 22 2.20 2.08E−02 3′ss CLL 156553242- 156553242- AGTGTCAGGAGC AGTGTCAGAAGG 156553591 156553588 CAGATTCTGTGC AGCCAGATTCTG GAGA (743) TGCG (744) 443 chr19: chr19: AGCCATTTATTT AGCCATTTATTT 11 53 2.17 2.14E−08 3′ss CLL 9728842- 9728855- GTCCCGTGGGAA GTCCCGTGGGTT 9730107 9730107 CCAATCTGCCCT TTTTTCCAGGGA TTTG (160) ACCA (161) 444 chr15: chr15: CCACTCTCACAA CCACTCTCACAA 1 8 2.17 1.41E−02 3′ss CLL 91448953- 91448953- TGACCCAGGAGG TGACCCAGGCTG 91449151 91449074 ACCCCCGGCGGC GATCAAGACCTT GCTT (745) TGAC (746) 445 chr1: chr1: TTGGAAGCGAAT TTGGAAGCGAAT 1 8 2.17 4.59E−02 3′ss CLL 23398690- 23398690- CCCCCAAGTCCT CCCCCAAGTGAT 23399766 23399784 TTGTTCTTTTGC GTATATCTCTCA AGTG (210) TCAA (211) 446 chr2: chr2: CCTTTACTTGGG AACCCGGAGAGA 1 8 2.17 4.13E−02 5′ss CLL 64457092- 64456774- GCTCTCAGCAAC AAAGGGAGCAAC 64478252 64478252 TGATGTTGCCAT TGATGTTGCCAT GCAG (747) GCAG (578) 447 chr14: chr14: GTGGGGGGCCAT GTGGGGGGCCAT 16 75 2.16 9.79E−09 3′ss CLL 23237380- 23237380- TGCTGCATTTTG TGCTGCATGTAC 23238985 23238999 TATTTTCCAGGT AGTCTTTGCCCG ACAG (122) CTGC (123) 448 chr15: chr15: ACTCAGATGCCG ACTCAGATGCCG 14 65 2.14 1.32E−05 3′ss CLL 74326871- 74326871- AAAACTCGCCCT AAAACTCGTGCA 74327483 74327512 CAGTCTGAGGTT TGGAGCCCATGG CTGT (748) AGAC (749) 449 chr10: chr10: GCCTACTCTTAA TCATCTTGAAAA 7 34 2.13 4.92E−03 exon CLL 89516679- 89516679- CCATTAGGGTGG ATGAAAATGTGG incl. 89519457 89527429 ATAGGCATGTAG ATAGGCATGTAG ACCT (750) ACCT (507) 450 chr20: chr20: TGGAGTGCGGAT TGGAGTGCGGAT 2 12 2.12 4.37E−03 3′ss CLL 33703761- 33703736- TTGCAACACTTG TTGCAACAATCA 33706400 33706400 CTTCCTTCTCCC AAGATCTGCGAG ACAT (751) ACCA (752) 451 chr12: chr12: CAACTGGAGTTC CAACTGGAGTTC 12 53 2.05 3.67E−06 3′ss CLL 105514375- 105514375- ATTTTCAGGTTT ATTTTCAGACTA 105514866 105514878 TTTGACAGACTA TGTATGAGCACT TGTA (753) TGGG (754) 452 chr1: chr1: CAATGTGTTGAC CAATGTGTTGAC 14 61 2.05 1.87E−03 3′ss CLL 155237988- 155237937- CATCGCAGTCCC CATCGCAGCCTC 155238083 155238083 CCTACAGCCCTG TCCTGCCAACTT TTCA (755) ACAG (756) 453 chr15: chr15: CAGCTGCTCTCA CAGCTGCTCTCA 16 67 2.00 7.47E−04 3′ss CLL 89870310- 89870294- GGAGAGAGTGGA GGAGAGAGGTAC 89870397 89870397 CTGGCTCTGTAG AAAGAAGACCCC GTAC (757) TGGC (758) 454 chr3: chr3: TCTCTAGTGGGC TCTCTAGTGGGC 8 35 2.00 7.53E−03 3′ss CLL 141272782- 141272782- CCTTCTAGTTCT CCTTCTAGGAAT 141274647 141274681 ACAAGGTAAAAC GACCAAAAGAAG TCTA (759) ACAA (760) 455 chr1: chr1: AGCTCCGAGAGG AGCTCCGAGAGG 2 11 2.00 6.28E−03 3′ss CLL 202122978- 202122963- GCAAGGAGCTCC GCAAGGAGAAAT 202123313 202123313 CTCCCTCCTAGA GTGTCCACTACT AATG (761) GGCC (762) 456 chrX: chrX: GACGTGGCAGCT GACGTGGCAGCT 19 73 1.89 1.20E−04 3′ss CLL 47315813- 47315797- CATGTGAGCATT CATGTGAGGCTT 47326808 47326808 GTGTCGTTACAG CAGTGTCATTTG GCTT (763) AGGA (764) 457 chr6: chr6: AAGGAAGAACAA AATGTTAAGGAG 2 10 1.87 4.93E−04 exon CLL 25975158- 25973513- GACTTTGTTTAG TCATCAAGTTAG incl. 25983391 25983391 TGTGACTCTGGA TGTGACTCTGGA TCCA (765) TCCA (766) 458 chr11: chr11: AGGAGAACACCT AGGAGAACACCT 15 55 1.81 1.53E−04 3′ss CLL 10876665- 10876633- TATTTCAGCTTT TATTTCAGAAAA 10877690 10877690 TATTTTTATGTG GGTGTACCATAC ATAA (767) CTGA (768) 459 chr9: chf9: CTGATGAAAACT CTGATGAAAACT 12 43 1.76 4.16E−05 3′ss CLL 93641235- 93641235- ACTACAAGACAC ACTACAAGGCCC 93648127 93650030 CTTACAGGCCAG AGACCCATGGAA GAGA (769) AGTG (723) 460 chr8: chr8: GGGGCCACCAGG GGGGCCACCAGG 21 72 1.73 2.11E−05 3′ss CLL 145313817- 145313817- TTGGCCAGCGGC TTGGCCAGGGCC 145314126 145314142 CCCCTTTCCCAG ATGGCTGAGCAC GGCC (770) GCAG (771) 461 chr7: chr7: TGCACACGCCTC TGCACACGCCTC 4 15 1.68 2.26E−02 3′ss CLL 98579583- 98579583- TCCTACAGAGTC TCCTACAGGCAG 98580862 98580886 TCTTATGCTGGT CCCAGCAAATCA CCCA (772) TCGA (773) 462 chr22: chr22: GAGCTGGAGAGG GAGCTGGAGAGG 14 46 1.65 2.74E−04 3′ss CLL 50660983- 50661021- AAGGCGAGAGGC AAGGCGAGGCAG 50662569 50662569 AGCTCGTCGGGA GCACTGGTCGAC GCAG (774) CACT (775) 463 chr6: chr6: GCCCCCGTTTTC GCCCCCGTTTTC 17 55 1.64 1.17E−04 3′ss CLL 31936315- 31936315- CTGCCCAGCCCT CTGCCCAGTACC 31936399 31936462 TGTCCTCAGTGC TGAAGCTGCGGG ACCC (307) AGCG (308) 464 chr7: chr7: CCGCCTCTGCCT CCGCCTCTGCCT 8 26 1.58 3.53E−03 3′ss CLL 64139714- 64139714- TCGGATAGGTCT TCGGATAGGAAA 64150776 64144464 GGCCCCACCCTG GGTTGAAAGAGC GAGT (776) CAAC (777) 465 chr12: chr12: TTTCTCATATTG TTTCTCATATTG 5 17 1.58 4.42E−03 3′ss CLL 51174021- 51174021- CTCAACAGTTCT CTCAACAGGTAT 51189680 51189691 TTTTTAGGTATC CATCTTTATCAG ATCT (778) AAAG (779) 466 chr11: chr11: AGTGGCTTTGGC AGTGGCTTTGGC 15 46 1.55 1.99E−03 intron CLL 126144916- 126144916- GTCTTATGGAGG GTCTTATGGGAT reten- 126144918 126145221 CTTGCTTGCAGA GGAGGACGAAGG tion GGGG (780) TTGG (781) 467 chr1: chr1: CATAGTGGAAGT CATAGTGGAAGT 20 60 1.54 6.97E−06 3′ss CLL 67890660- 67890642- GATAGATCTTCT GATAGATCTGGC 67890765 67890765 TTTTCACATTAC CTGAAGCACGAG AGTG (444) GACA (445) 468 chr1: chr1: GGTGACACTCAA GGTGACACTCAA 22 65 1.52 1.10E−05 3′ss CLL 157771381- 157771367- CTTCACAGGTCT CTTCACAGTGCC 157771704 157771704 CTCCCTCTAGTG TACTGGGGCCAG CCTA (782) AAGC (783) 469 chr2: chr2: GGCAACTTCGTT GGCAACTTCGTT 27 76 1.46 7.08E−07 3′ss CLL 106781255- 106781240- AATATGAGCTTT AATATGAGGTCT 106782511 106782511 CTACTCAACAGG ATCCAGGAAAAT TCTA (375) GGTG (376) 470 chr14: chr14: CGCTCTCCGCCT AGGGAGACGTTC 19 54 1.46 2.09E−04 exon CLL 75348719- 75349327- TCCAGAAGGGGT CCTGCCTGGGGT skip 75352288 75352288 CTCCTTATGCCA CTCCTTATGCCA GGGA (208) GGGA (209) 471 chr2: chr2: TTTCCATTGGGC GAGGGCCACCAA 3 10 1.46 4.35E−02 exon CLL 153551136- 153551136- CAATCAAGATGC TGGGACAAATGC incl. 153571063 153572508 CTGGAATGATGT CTGGAATGATGT CGTC (784) CGTC (785) 472 chrX: chrX: AGAGACAAAGAG AGAGACAAAGAG 33 92 1.45 4.85E−06 3′ss CLL 118759359- 118759342- AAGAAAAACTCT AAGAAAAATTAA 118763280 118763280 TACTGTTTTACA CTCTGCTGTTTG GTTA (786) CTGC (787) 473 chr17: chr17: CTCACCAGCGCC CTCACCAGCGCC 5 15 1.42 1.43E−03 exon CLL 27238402- 27238255- ATCGTCAGCTCT ATCGTCAGATGG incl. 27239499 27239499 AGGAGTTCCAGA CAAGGTCAGCCC GCCT (788) CGGC (789) 474 chr12: chr12: ATCAGGTGCTCA ATCAGGTGCTCA 11 30 1.37 9.13E−04 3′ss CLL 50821692- 50821692- TCCTGAGGTGTC TCCTGAGGGTAA 50822699 50822717 TGTCTTTAATAC TGCAGAGCTCTC AGGT (790) AGAA (791) 475 chr6: chr6: TCTGGCAGCCCA TCTGGCAGCCCA 17 45 1.35 1.98E−04 3′ss CLL 43152643- 43152643- CGATGCTGCAAG CGATGCTGGGAG 43153228 43153193 ATGGCATCGAGC TCGGGCTCACGT AGCA (792) CCTT (793) 476 chr3: chr3: AGAATTTTAAGA AGAATTTTAAGA 11 29 1.32 1.64E−03 3′ss CLL 3186394- 3186394- TACTTCAGATTT TACTTCAGGTTT 3188099 3188113 TGTCTTGTAGGT TATGGGAGAATT TTTA (794) GTAG (795) 477 chr7: chr7: CCGCCTCTGCCT CCGCCTCTGCCT 1 4 1.32 2.43E−02 3′ss CLL 64139714- 64139714- TCGGATAGGCTT TCGGATAGGAAA 64150765 64144464 TATTTAGGTCTG GGTTGAAAGAGC GCCC (796) CAAC (777) 478 chr3: chr3: GAGCTAGTCAGA AAATTCTTGACC 15 38 1.29 1.66E−02 exon CLL 56606456- 56605330- CTTTAGAGGAAA AATCTAGGGAAA incl. 56626997 56626997 CAGTACTGCTGG CAGTACTGCTGG AGCA (797) AGCA (798) 479 chr22: chr22: CTTCATCTGTGG CTTCATCTGTGG 25 61 1.25 5.02E−06 3′ss CLL 24043032- 24037704- ATAAGCAGGTCA ATAAGCAGTGCA 24047615 24047615 TGTCCTCCAGGT GGCCAAGGCCCC TTCT (799) CTGC (800) 480 chr17: chr17: CCGGAGCCCCTT CCGGAGCCCCTT 8 20 1.22 1.07E−02 3′ss CLL 45229302- 45229284- CAAAAAAGACTT CAAAAAAGTCTG 45232037 45232037 TTCGTGTTTTAC TTGCCAGAATCG AGTC (327) GCCA (328) 481 chr1: chr1: AGTATGGGATAT TCATTCTTATTT 8 20 1.22 2.03E−02 exon CLL 62149218- 62149218- TTTAAAAGATTG CAATGCAGATTG incl. 62152463 62160368 TTGGACCTTCAG TTGGACCTTCAG ATGG (801) ATGG (802) 482 chr22: chr22: CTTTATCTGTGC CTTCATCTGTGG 31 73 1.21 1.26E−05 exon CLL 24037704- 24037704- ATGAACAGTGCA ATAAGCAGTGCA incl. 24042912 24047615 GGCCAAGGCCCC GGCCAAGGCCCC CTGC (803) CTGC (800) 483 chr7: chr7: AAGTCGTCCTCT AGAGAGAAACAT 18 42 118 2.78E−02 exon CLL 104844232- 104844232- TCAGAAAGGCCG CCGAAAAAGCCG incl. 104909252 105029094 GAGCCTCAACAG GAGCCTCAACAG AAAG (804) AAAG (805) 484 chr2: chr2: TGGGCTACCTTA TGGGCTACCTTA 23 53 1.17 3.28E−02 exon CLL 85779690- 85779104- ACCCTGGGGTAT ACCCTGGGGATT incl. 85780061 85780061 TTACACAGAGTC TTTGACCCTCGT GGCG (806) GTGG (807) 485 chr1: chr1: GACTGCCCTAAA GACTGCCCTAAA 10 23 1.13 4.92E−03 3′ss CLL 52902647- 52902635- AGGAAAAGTTTA AGGAAAAGACTA 52903891 52903891 CTGTTTAGACTA AAGAAGAAAGAC AAGA (808) AGTG (809) 486 chr3: chr3: TGATAGTTGGAG TGATAGTTGGAG 11 25 1.12 3.47E−03 3′ss CLL 179065598- 179065598- CGGAGACTCATA CGGAGACTTAGC 179066635 179066632 ATGGCAGAACCT ATAATGGCAGAA GTTT (810) CCTG (811) 487 chr1: chr1: TCATTCTTATTT TCATTCTTATTT 5 12 112 3.19E−02 exon CLL 62152593- 62149218- CAATGCAGAGAC CAATGCAGATTG incl. 62160368 62160368 AGGGTCTTGCTC TTGGACCTTCAG TGTT (812) ATGG (802) 488 chr19: chr19: TGACGGTGCCAC TGACGGTGCCAC 30 65 1.09 4.13E−02 exon CLL 53935281- 53935281- CGCGGCGCTTTT CGCGGCGCAGAG incl. 53936832 53945048 CTCCCTTAGATG GAGTCTGCAATG CCTT (813) CCGA (814) 489 chr19: chr19: GCAGTGGCTGGA GCAGTGGCTGGA 42 85 1.00 4.02E−05 3′ss CLL 19414656- 19414721- GATCAAAGTTTC GATCAAAGAGAG 19416657 19416657 ACCCCCAGAGGG AGTGTGCCTATT AGCC (815) GACT (816) 490 chrX: chrX: GGACGATGGGGA GGACGATGGGGA 3 7 1.00 8.68E−03 3′ss CLL 47103949- 47103949- TGAGAAAGATGA TGAGAAAGAAGA 47104083 47104080 CGAGGAGGATAA TGACGAGGAGGA AGAT(817) TAAA(818) 491 chr5: chr5: ACTCTTATGCAG ACTCTTATGCAG 24 48 0.97 7.63E−03 3′ss CLL 1579599- 1581810- TCCCCATGGACT TCCCCATGAGGA 1585098 1585098 GAACCATCAAGA GATCCTAGTCTC CACC(819) ACCA(531) 492 chr17: chr17: GACCCATGCATC GACCCATGCATC 47 93 0.97 2.22E−02 3′ss CLL 73587327- 73587327- CTCCTGTGCTCC CTCCTGTGTGGG 73587681 73587696 TCCCACTGCAGT CACAGTGGCTCA GGGC(820) GGGA(821) 493 chr18: chr18: CCAAGTTTTGTG CCAAGTTTTGTG 38 75 0.96 7.90E−03 3′ss CLL 224200- 224179- AAAGAAAGTGTA AAAGAAAGAACA 224923 224923 TGTTTTGTTCAC TCAGATACCAAA GACA(116) CCTA(117) 494 chr16: chr16: CATCAAGCAGCT CATCAAGCAGCT 10 20 0.93 2.86E−02 3′ss CLL 57473207- 57473246- GTTGCAATGTTT GTTGCAATCTGC 57474683 57474683 AGTCCCAGGAAG CCACAAAGAATC CACC(822) CAGC(823) 495 chr7: chr7: TGAGAGTCTTCA TGAGAGTCTTCA 45 86 0.92 7.69E−08 3′ss CLL 99943591- 99943591- GTTACTAGTTTG GTTACTAGAGGC 99947339 99947421 TCTTTCCTAGAT GGATTTCCCTGA CCAG(420) CTGA(421) 496 chr12: chr12: CAATCATTGACA CAATCATTGACA 29 54 0.87 3.27E−02 3′ss CLL 47599928- 47599852- ATATTATGACCC ATATTATGGAAC 47600293 47600293 TGCATGTGATGG TGACTCAGCGCA ATCA(824) AGAA(825) 497 chr9: chf9: GGGACACTGTGC GGGACACTGTGC 43 72 0.73 1.74E−02 3′ss CLL 140633231- 140633231- CGAATGAACTTG CGAATGAACAGC 140637822 140637843 CTTGCCTTTTGT TGCAGTATCTCG TTTA(826) GAAG(827) 498 chr19: chr19: TCAGGGGGCGCG TCGAGCCAGGCT to 17 0.71 2.37E−02 exon CLL 17654242- 17654440- TGCTGAAGGAGC GCAAAAAGGAGC skip 17657494 17657494 TGCCTGAGTTCG TGCCTGAGTTCG AGGG(828) AGGG(829) 499 chr6: chr6: CTACAACCAGAG CTACAACCAGAG 57 92 0.68 2.50E−03 3′ss CLL 29691704- 29691704- CGAGGCTGGGTC CGAGGCTGGGAA 29691949 29691966 TCACACCCTCCA TGAATGGCTGCG GGGA(830) ACAT(831) 500 chr20: chr20: TGCCTAAGGCGG TGCCTAAGGCGG 54 87 0.68 4.59E−02 3′ss CLL 30310151- 30310133- ATTTGAATCTCT ATTTGAATAATC 30310420 30310420 TTCTCTCCCTTC TTATCTTGGCTT AGAA(479) TGGA(480) 501 chr4: chr4: TCCAACAAGCAC TCCAACAAGCAC 55 87 0.65 1.64E−04 3′ss CLL 17806394- 17806379- CTCTGAAGTCTT CTCTGAAGGTTA 17806729 17806729 CTCATTCACAGG AGGCTACCTTTC TTAA(832) CAGA(833) 502 chr9: chr9: CACCACAAAATC CACCACAAAATC 41 65 0.65 4.07E−03 3′ss CLL 140622981- 140622981- ACAGACAGCTTG ACAGACAGCAGC 140637822 140637843 CTTGCCTTTTGT TGCAGTATCTCG TTTA(458) GAAG(459) 503 chr1: chr1: GAATCCGTATCT GAATCCGTATCT 45 70 0.63 4.59E−02 3′ss CLL 155278756- 155278756- GGGAACAGAGCC GGGAACAGAATG 155279833 155279854 CTTTGCTCCTCC AACGGAGACCAG CTCA(432) AATT(433) 504 chr17: chr17: GTTCCCGAGGCT GTTCCCGAGGCT 60 90 0.58 8.49E−05 3′ss CLL 40690773- 40690773- GTCACCAGGGTG GTCACCAGTGGA 40692967 40695045 TTCCCTCAGGTC TACTGAGGCTGT AATG (834) GTGG (835) 505 chr12: chr12: ATTTCCAGAGGA ATTTCCAGAGGA 51 76 0.57 1.45E−05 3′ss CLL 95660408- 95660408- TTTACACTTTTG TTTACACTGGTC 95663814 95663826 CTTGACAGGGTC AGTGCTGCTTGC AGTG (462) CCAT (463) 506 chr3: chr3: CCAGATCAACAC CCAGATCAACAC 44 65 0.55 2.77E−02 3′ss CLL 133371473- 133371458- AATTGATAGTCG AATTGATAATGT 133372188 133372188 TACTCTTTCAGA CAGCAATATTTC TGTC (836) CAAC (837) 507 chr19: chr19: CGTCCTGCCCCC CGTCCTGCCCCC 67 94 0.48 2.30E−02 3′ss CLL 7075116- 7075116- AACTGCCGCTCT AACTGCCGCCTC 7075665 7075686 GTCTTCCCTGTT TCAGCGAGAAGG CCCA (838) ACAC (839) 508 chr10: chr10: TGACGTTCTCTG TGACGTTCTCTG 53 74 0.47 2.22E−03 3′ss CLL 75554088- 75554088- TGCTCCAGTGGT TGCTCCAGGTTC 75554298 75554313 TTCTCCCACAGG CCGGCCCCCAAG TTCC (466) TCGC (467) 509 chr19: chr19: TGCAGGGGGAGC TGCAGGGGGAGC 48 66 0.45 6.62E−03 3′ss CLL 11558433- 11558433- AGCCCAAGGAGG AGCCCAAGCCGG 11558507 11558537 CCCCACCGCCAC CCAGCCCTGCTG TGTC (840) AGGA (841) 510 chr1: chr1: GACTGCCCTAAA GACTGCCCTAAA 55 74 0.42 8.74E−03 3′ss CLL 52902650- 52902635- AGGAAAAGCAGT AGGAAAAGACTA 52903891 52903891 TTACTGTTTAGA AAGAAGAAAGAC CTAA (842) AGTG (809) 511 chr17: chr17: CTATGAGGCCAT GTTCCCGAGGCT 68 87 0.35 1.45E−03 exon CLL 40693224- 40690773- GACTGCAGTGGA GTCACCAGTGGA incl. 40695045 40695045 TACTGAGGCTGT TACTGAGGCTGT GTGG (843) GTGG (835) 512 chr5: chr5: CTTCTCAAGATC CTTCTCAAGATC 70 86 0.29 2.73E−02 3′ss CLL 139865317- 139865317- AGTCTCAGGTGC AGTCTCAGGAAC 139866542 139866590 CACGTGTGCCAA CTGACAGAACTT CGCA (844) CACA (845) 513 chr6: chr6: ACCTTAACAAGA AATCACTAGGAA 58 71 0.29 1.38E−02 exon CLL 127636041- 127636041- TTTATGAGACTT CTCCAGAGACTT incl. 127637594 127648146 CCTTTAATAAGT CCTTTAATAAGT GTTG (846) GTTG (847) 514 chr4: chr4: ACTGGGCTTCCA ACTGGGCTTCCA 60 72 0.26 4.54E−02 exon CLL 54266006- 54266006- CCGAGCAGAAAC CCGAGCAGGAGA incl. 54280781 54292038 AGCACTTCTTCT TTACCTGGGGCA CAGT (848) ATTG (849) 515 chr9: chf9: CTGAAGACGGGA CTGAAGACGGGA 87 92 0.08 2.80E−02 3′ss CLL 130566979- 130566979- TTCTTTAGCTCT TTCTTTAGGTTC 130569251 130569270 CCCCACCTGGTG GGGAGCGGATCC CAGG (850) GCAT (851) 516 chr17: chr17: ATCTCAGGAGCA CCCACCCCTTCA 93 98 0.07 4.18E−03 5′ss CLL 72759659- 72760785- CCTGAATGGTCC CCCTGCAGGTCC 72763074 72763074 CCTGCCTGTGCC CCTGCCTGTGCC CTTC (852) CTTC (853) 517 chr2: chr2: AGCAAGTAGAAG AGCAAGTAGAAG 0 72 6.19 1.51E−10 3′ss Mel. 109102364- 109102364- TCTATAAAATTT TCTATAAAATAC 109102954 109102966 ACCCCCAGATAC AGCTGGCTGAAA AGCT (1) TAAC (2) 518 chr19: chr19: GGCCCTTTTGTC GGCCCTTTTGTC 0 72 6.19 7.67E−09 3′ss Mel. 57908542- 57908542- CTCACTAGCATT CTCACTAGGTTC 57909780 57909797 TCTGTTCTGACA TTGGCATGGAGC GGTT (7) TGAG (8) 519 chr2: chr2: TGACCACGGAGT TGACCACGGAGT 0 59 5.91 1.12E−08 3′ss Mel. 232196609- 232196609- ACCTGGGGCCCT ACCTGGGGATCA 232209660 232209686 TTTTTCTCTTTC TGACCAACACGG CTTC (37) GGAA (38) 520 chr1: chr1: CAAGTATATGAC CAAGTATATGAC 0 56 5.83 3.98E−05 3′ss Mel. 245246990- 245246990- TGAAGAAGATCC TGAAGAAGGTGA 245288006 245250546 TGAATTCCAGCA GCCTTTTTCTCA AAAC (21) AGAG (22) 521 chr11: chr11: GGCCACACGCCT GGCCACACGCCT 0 54 5.78 1.58E−06 3′ss Mel. 65635911- 65635892- CTGCCAAGCCCC CTGCCAAGACAT 65635980 65635980 TCTCCCCTGGCA TGATGAGTGTGA CAGA (854) GTCT (855) 522 chr3: chr3: TGCAGTTTGGTC TGCAGTTTGGTC 0 49 5.64 5.19E−07 3′ss Mel. 9960293- 9960293- AGTCTGTGCCTT AGTCTGTGGGCT 9962150 9962174 CCTCACCCCTCT CTGTGGTATATG CCTC (23) ACTG (24) 523 chr3: chr3: GAGTACGAGGTC GAGTACGAGGTC 0 48 5.61 2.52E−15 3′ss Mel. 48457878- 48457860- TCCAGCAGCCTG TCCAGCAGCCTC 48459319 48459319 CCCTGTGCCTAC GTGTGCATCACC AGCC (856) GGGG (857) 524 chr1O: chr1O: TACCTCTGGTTC TACCTCTGGTTC 0 47 5.58 5.54E−06 3′ss Mel. 99214556- 99214556- CTGTGCAGTCTT CTGTGCAGTTCT 99215395 99215416 CGCCCCTCTTTT GTGGCACTTGCC CTTA (13) CTGG (14) 525 chr1: chr1: TCTTTGGAAAAT TCTTTGGAAAAT 0 45 5.52 3.06E−06 3′ss Mel. 101458310- 101458296- CTAATCAATTTT CTAATCAAGGGA 101460665 101460665 CTGCCTATAGGG AGGAAGATCTAT GAAG (25) GAAC (26) 526 chr9: chr9: AGCGCATCGCAG AGCGCATCGCAG 0 45 5.52 1.42E−03 3′ss Mel. 90582559- 90582574- CTTCCAAGTACT CTTCCAAGGCTC 90584108 90584108 TCTTCACAGCTC TCCTCCATCAGT CCCT (858) ACTT (859) 527 chr1: chr1: TCACTCAAACAG TCACTCAAACAG 0 44 5.49 1.90E−07 3′ss Mel. 179835004- 179834989- TAAACGAGTTTT TAAACGAGGTAT 179846373 179846373 ATCATTTACAGG GTGACGCATTCC TATG (53) CAGA (54) 528 chr14: chr14: AGTTAGAATCCA AGTTAGAATCCA 0 41 5.39 4.30E−08 3′ss Mel. 74358911- 74358911- AACCAGAGTGTT AACCAGAGCTCC 74360478 74360499 GTCTTTTCTCCC TGGTACAGTTTG CCCA (61) TTCA (62) 529 chr11: chr11: TGGGCAGCCCCC TGGGCAGCCCCC 0 39 5.32 2.61E−02 3′ss Mel. 117167925- 117167677- CGCAGACGTTGG CGCAGACGCTCA 117186250 117186250 TTTTTCAGCAGA ACATCCTGGTGG CCTG (860) ATAC (861) 530 chr20: chr20: AGAACTGCACCT AGAACTGCACCT 0 36 5.21 6.58E−07 3′ss Mel. 62701988- 62701988- ACACACAGCCCT ACACACAGGTGC 62703210 62703222 GTTCACAGGTGC AGACCCGCAGCT AGAC (29) CTGA (30) 531 chr18: chr18: AGAAAGAGCATA AGAAAGAGCATA 0 33 5.09 6.82E−09 3′ss Mel. 33605641- 33573263- AATTGGAAATAT AATTGGAAGAGT 33606862 33606862 TGGACATGGGCG ACAAGCGCAAGC TATC (91) TAGC (92) 532 chr3: chr3: AACCAAGAGGAC AACCAAGAGGAC 0 32 5.04 1.83E−02 3′ss Mel. 52283338- 52283338- CCACACAGGATG CCACACAGGTTC 52283671 52283685 GTCTTCACAGGT TCAAAGCTGGCC TCTC (862) CAGA (863) 533 chr9: chr9: AAATGAAGAAAC AAATGAAGAAAC 0 32 5.04 6.82E−09 3′ss Mel. 125759640- 125759640- TCCTAAAGCCTC TCCTAAAGATAA 125760854 125760875 TCTCTTTCTTTG AGTCCTGTTTAT TTTA (67) GACC (68) 534 chr12: chr12: AATATTGCTTTA AATATTGCTTTA 0 31 5.00 9.14E−06 3′ss Mel. 116413154- 116413118- CCAAACAGGGAC CCAAACAGGTCA 116413319 116413319 CCCTTCCCCTTC CGGAGGAGTAAA CCCA (77) GTAT (78) 535 chr18: chr18: TTGGACCGGAAA TTGGACCGGAAA 1 62 4.98 1.13E−06 3′ss Mel. 683395- 683380- AGACTTTGAGTC AGACTTTGATGA 685920 685920 TCTTTTTGCAGA TGGATGCCAACC TGAT (15) AGCG (16) 536 chr1: chr1: ATCAGAAATTCG ATCAGAAATTCG 0 29 4.91 8.06E−03 3′ss Mel. 212515622- 212515622- TACAACAGGTTT TACAACAGCTCC 212519131 212519144 CTTTTAAAGCTC TGGAGCTTTTTG CTGG (65) ATAG (66) 537 chr1: chr1: CTCAGAGCCAGG CTCAGAGCCAGG 0 29 4.91 3.06E−05 3′ss Mel. 35871069- 35871069- CTGTAGAGATGT CTGTAGAGTCCG 35873587 35873608 TTTCTACCTTTC CTCTATCAAGCT CACA (105) GAAG (106) 538 chrX: chrX: GTCTTGAGAATT ACTTCCTTAGTG 0 29 4.91 1.16E−06 5′ss Mel. 47059943- 47059013- GGAAGCAGGTGG GTTTCCAGGTGG 47060292 47060292 TGGTGCTCACCA TGGTGCTCACCA ACAC (113) ACAC (112) 539 chr2: chr2: AAATTTAACATT AAATTTAACATT 0 28 4.86 3.75E−06 3′ss Mel. 24207701- 24207701- ACTCATAGTTTT ACTCATAGAGTA 24222524 24222541 TGCTGTTTTACA AGCCATATCAAA GAGT (546) GACT (547) 540 chr5: chr5: CTCCATGCTCAG CTCCATGCTCAG 0 28 4.86 8.03E−04 3′ss Mel. 869519- 865696- CTCTCTGGTTTC CTCTCTGGGGAA 870587 870587 TTTCAGGGCCTG GGTGAAGAAGGA CCAT (128) GCTG (129) 541 chr20: chr20: ACATGAAGGTGG ACATGAAGGTGG 0 27 4.81 4.86E−06 3′ss Mel. 34144042- 34144042- ACGGAGAGGCTC ACGGAGAGGTAC 34144725 34144743 CCCTCCCACCCC TGAGGACAAATC AGGT (49) AGTT (50) 542 chr2: chr2: TGGGAGGAGCAT TGGGAGGAGCAT 0 27 4.81 1.72E−04 3′ss Mel. 97285513- 97285499- GTCAACAGAGTT GTCAACAGGACT 97297048 97297048 TCCCTTATAGGA GGCTGGACAATG CTGG (9) GCCC (10) 543 chr19: chr19: AGCCATTTATTT AGCCATTTATTT 1 54 4.78 1.18E−09 3′ss Mel. 9728842- 9728855- GTCCCGTGGGAA GTCCCGTGGGTT 9730107 9730107 CCAATCTGCCCT TTTTTCCAGGGA TTTG (160) ACCA (161) 544 chr15: chr15: ATATTCCTTTTA ATATTCCTTTTA 0 25 4.70 3.65E−06 3′ss Mel. 49420970- 49420957- TTTCTAAGTCTT TTTCTAAGGAGT 49421673 49421673 TTGTCTTAGGAG TAAACATAGATG TTAA (864) TAGC (865) 545 chr12: chr12: ATTTGGACTCGC ATTTGGACTCGC 1 49 4.64 6.42E−06 3′ss Mel. 105601825- 105601807- TAGCAATGATGT TAGCAATGAGCA 105601935 105601935 CTGTTTATTTTT TGACCTCTCAAT AGAG (41) GGCA (42) 546 chr14: chr14: AGATGTCAGGTG AGATGTCAGGTG 0 24 4.64 2.35E−03 3′ss Mel. 75356052- 75356052- GGAGAAAGCCTT GGAGAAAGCTGT 75356580 75356599 TGATTGTCTTTT TGGAGACACAGT CAGC (89) TGCA (90) 547 chr11: chr11: CATAAAATTCTA CATAAAATTCTA 0 23 4.58 4.56E−05 3′ss Mel. 4104212- 4104212- ACAGCTAATTCT ACAGCTAAGCAA 4104471 4104492 CTTTCCTCTGTC GCACTGAGCGAG TTCA (69) GTGA (70) 548 chr15: chr15: GAAACCAACTAA GAAACCAACTAA 0 23 4.58 2.75E−04 3′ss Mel. 59209219- 59209198- AGGCAAAGCCCA AGGCAAAGGTAA 59224554 59224554 TTTTCCTTCTTT AAAACATGAAGC CGCA (101) AGAT (102) 549 chr22: chr22: CTGGGAGGTGGC CTGGGAGGTGGC 0 23 4.58 1.03E−06 3′ss Mel. 19044699- 19044675- ATTCAAAGCCCC ATTCAAAGGCTC 19050714 19050714 ACCTTTTGTCTC TTCAGAGGTGTT CCCA (45) CCTG (46) 550 chr3: chr3: CACTGCTGGGAG CACTGCTGGGAG 0 23 4.58 5.29E−10 3′ss Mel. 129284872- 129284860- AGTGGAAGTTGC AGTGGAAGATTC 129285369 129285369 TTCCACAGATTC CTGAGAGCTGCC CTGA (524) GGCC (525) 551 chr9: chr9: GGTCCTGAACGC GGTCCTGAACGC 0 23 4.58 1.89E−04 3′ss Mel. 138903859- 138903870- TGTGAAATAACT TGTGAAATTGTA 138905044 138905044 TCGCCCCCAGCT CTGTCAGAACTT TCAA (866) CGCC (867) 552 chr6: chr6: TGGAGCAGTATG TGGAGCAGTATG 0 22 4.52 8.93E−03 3′ss Mel. 35255622- 35255622- CCAGCAAGACTT CCAGCAAGGTTC 35258029 35258042 TTCCCCCAGGTT TTCATGACAGCC CTTC (868) AGAT (869) 553 chr8: chr8: TCGTGCAGACCC TCGTGCAGACCC 0 22 4.52 3.21E−11 3′ss Mel. 28625893- 28625839- TGGAGAAGATCT TGGAGAAGCATG 28627405 28627405 CACAGATGTGCA GCTTCAGTGATA GTCT (870) TTAA (871) 554 chr6: chr6: CCGGGGCCTTCG CCGGGGCCTTCG 2 67 4.5 2.74E−12 3′ss Mel. 10723474- 10723474- TGAGACCGCTTG TGAGACCGGTGC 10724788 10724802 TTTTCTGCAGGT AGGCCTGGGGTA GCAG (95) GTCT (96) 555 chr4: chr4: GTGCCAACGAGG GTGCCAACGAGG 2 65 4.46 9.90E−07 3′ss Mel. 184577127- 184577114- ACCAGGAGTTCT ACCAGGAGATGG 184580081 184580081 TTATTTCAGATG AACTAGAAGCAT GAAC (734) TACG (735) 556 chr22: chr22: CTCTCTCCAACC CTCTCTCCAACC 0 21 4.46 4.84E−04 3′ss Mel. 39064137- 39064137- TGCATTCTCATC TGCATTCTTTGG 39066874 39066888 TCGCCCACAGTT ATCGATCAACCC GGAT (140) GGGA (141) 557 chr9: chr9: TTGAAGCTCAGT TTGAAGCTCAGT 0 21 4.46 3.30E−03 3′ss Mel. 37501841- 37501841- GAGAAAAGTTCT GAGAAAAGGATG 37503015 37503039 TCTGTTTATGTC ATGGAGATAGCC TTCC (872) AAAG (873) 558 chr14: chr14: CAGTTATAAACT CAGTTATAAACT 0 20 4.39 2.55E−03 3′ss Mel. 71059726- 71059705- CTAGAGTGAGTT CTAGAGTGCTTA 71060012 71060012 TATTTTCCTTTT CTGCAGTGCATG ACAA (79) GTAT (80) 559 chr17: chr17: GGAGCAGTGCAG GGAGCAGTGCAG 0 20 4.39 2.74E−12 3′ss Mel. 71198039- 71198039- TTGTGAAATCAT TTGTGAAAGTTT 71199162 71199138 TACTTCTAGATG TGATTCATGGAT ATGC (31) TCAC (32) 560 chr9: chr9: CGCCCTGACACA CGCCCTGACACA 0 20 4.39 1.26E−04 3′ss Mel. 35608506- 35608506- CAATCAGGACTT CAATCAGGGCTC 35608842 35608858 CTCTATCTACAG TGTTGCAAGAGG GCTC (874) GGGT (875) 561 chrX: chrX: ACTTCCTTAGTG ACTTCCTTAGTG 0 20 4.39 2.32E−03 3′ss Mel. 47059013- 47059013- GTTTCCAGGTTG GTTTCCAGGTGG 47059808 47060292 CCAGGGCACTGC TGGTGCTCACCA AGCT (111) ACAC (112) 562 chr12: chr12: CTTGGAGCTGAC CTTGGAGCTGAC 4 96 4.28 5.10E−13 3′ss Mel. 107378993- 107379003- GCCGACGGGGAA GCCGACGGTTTA 107380746 107380746 CTGACAAGATCA TTGCAGGGAACT CATT (130) GACA (131) 563 chr10: chr10: TTGCTGGCCATC TTGCTGGCCATC 0 18 4.25 1.13E−14 3′ss Mel. 133782836- 133782073- GGATTGGGCCCT GGATTGGGGATC 133784141 133784141 TCGTTTCAGGAT TATATTGGAAGG GGAT (876) CGTC (877) 564 chr11: chr11: CCACCGCCATCG CCACCGCCATCG 0 18 4.25 6.04E−04 3′ss Mel. 64877395- 64877395- ACGTGCAGTACC ACGTGCAGGTGG 64877934 64877953 TCTTTTTACCAC GGCTCCTGTACG CAGG (167) AAGA (168) 565 chr21: chr21: ATCATAGCCCAC ATCATAGCCCAC 1 35 4.17 1.72E−04 3′ss Mel. 37416267- 37416254- ATGTCCAGTTTT ATGTCCAGGTAA 37417879 37417879 TCTTTCTAGGTA AAGCAGCGTTTA AAAG (695) ATGA (696) 566 chr15: chr15: TGATTCCAAGCA TGATTCCAAGCA 1 34 4.13 1.03E−06 3′ss Mel. 25213229- 25213229- AAAACCAGCCTT AAAACCAGGCTC 25219533 25219457 CCCCTAGGTCTT CATCTACTCTTT CAGA (230) GAAG (231) 567 chr17: chr17: TACTGAAATGTG TACTGAAATGTG 0 16 4.09 5.46E−04 3′ss Mel. 34942628- 34942628- ATGAACATATCC ATGAACATATCC 34943454 34943426 AGGTAATCGAGA AGAAGCTTGGAA GACC (124) GCTG (125) 568 chr2: chr2: CCATTCGAGAGC CCATTCGAGAGC 0 16 4.09 2.25E−03 3′ss Mel. 219610954- 219610954- ATCAGAAGATTG ATCAGAAGCTAA 219611752 219611725 GGAGGAAGGACC ACCATTTCCCAG GGCT (878) GCTC (879) 569 chr10: chr10: TCTTGCCAGAGC TCTTGCCAGAGC 0 15 4.00 9.94E−07 3′ss Mel. 99219232- 99219283- TGCCCACGCTCT TGCCCACGCTTC 99219415 99219415 CCACCCTCAGCT TTTCCTTGCTGC GCCT (587) TGGA (588) 570 chr11: chr11: AGATCGCCTGGC AGATCGCCTGGC 0 15 4.00 9.65E−05 3′ss Mel. 3697619- 3697606- TCAGTCAGTTTT TCAGTCAGACAT 3697738 3697738 TCTCTCTAGACA GGCCAAACGTGT TGGC (187) AGCC (188) 571 chr11: chr11: CGGCGCGGGCAA CGGCGCGGGCAA 0 15 4.00 4.00E−05 3′ss Mel. 62648919- 62648919- CCTGGCGGCCCC CCTGGCGGGTCT 62649352 62649364 CATTTCAGGTCT GAAGGGGCGTCT GAAG (165) CGAT (166) 572 chr1: chr1: TCAGGAGCAGAG CTCAGGGAAGGG 0 15 4.00 2.96E−02 5′ss Mel. 113195986- 113192091- AGGAAAAGTGCA GCAGCACATGCA 113196219 113196219 TTTGCCCAGTAT TTTGCCCAGTAT AACA (880) AACA (881) 573 chr1: chr1: CGATCTCCCAAA CGATCTCCCAAA 0 15 4.00 5.55E−03 3′ss Mel. 52880319- 52880319- AGGAGAAGTCTG AGGAGAAGCCCC 52880412 52880433 ACCAGTCTTTTC TCCCCTCGCCGA TACA (55) GAAA (56) 574 chr15: chr15: TCACACAGGATA GCCTCACTGAGC 1 30 3.95 6.03E−06 exon Mel. 25212299- 25207356- ATTTGAAAGTGT AACCAAGAGTGT incl. 25213078 25213078 CAGTTGTACCCG CAGTTGTACCCG AGGC (164) AGGC (145) 575 chr11: chr11: TGCAGCTGGCCC TGCAGCTGGCCC 0 14 3.91 1.39E−07 3′ss Mel. 64002365- 64002365- CCGCCCAGGTCT CCGCCCAGGCCC 64002911 64002929 TTTCTCTCCCAC CTGTCTCCCAGC AGGC (638) CTGA (639) 576 chr12: chr12: GCCTGCCTTTGA GCCTGCCTTTGA 0 14 3.91 1.83E−03 3′ss Mel. 113346629- 113346629- TGCCCTGGATTT TGCCCTGGGTCA 113348840 113348855 TGCCCGAACAGG GTTGACTGGCGG TCAG (71) CTAT (72) 577 chr17: chr17: CCAAGCTGGTGT CCAAGCTGGTGT 0 14 3.91 1.08E−03 3′ss Mel. 78188582- 78188564- GCGCACAGGCCT GCGCACAGGCAT 78188831 78188831 CTCTTCCCGCCC CATCGGGAAGAA AGGC (73) GCAC (74) 578 chr2: chr2: GTGTGGCAAGTA GTGTGGCAAGTA 0 14 3.91 1.45E−02 3′ss Mel. 85848702- 85848702- CTTTCAAGTATC CTTTCAAGGCCG 85850728 85850768 TGCCCTTCTATT GGGTTTGAAGTC ACAG (882) TCAC (883) 579 chr12: chr12: AAAATCATTGAT AAAATCATTGAT 0 13 3.81 1.44E−03 3′ss Mel. 29450133- 29450133- TCCCTTGAAATT TCCCTTGAGTGG 29460566 29460590 CTCTTTACTCTA TTAGACGATGCT CCTT (884) ATTA (885) 580 chr14: chr14: GTGGGGGGCCAT GTGGGGGGCCAT 0 13 3.81 2.75E−04 3′ss Mel. 23237380- 23237380- TGCTGCATTTTG TGCTGCATGTAC 23238985 23238999 TATTTTCCAGGT AGTCTTTGCCCG ACAG (122) CTGC (123) 581 chr22: chr22: CGCTGGCACCAT CGCTGGCACCAT 0 13 3.81 5.09E−08 3′ss Mel. 36627480- 36627512- GAACCCAGTATT GAACCCAGAGAG 36629198 36629198 TCCAGGACCAAG CAGTATCTTTAT TGAG (199) TGAG (200) 582 chr19: chr19: TGCCTGTGGACA TGCCTGTGGACA 0 12 3.70 4.53E−04 3′ss Mel. 14031735- 14031735- TCACCAAGCCTC TCACCAAGGTGC 14034130 14034145 GTCCTCCCCAGG CGCCTGCCCCTG TGCC (59) TCAA (60) 583 chr20: chr20: TTTGCAGGGAAT TTTGCAGGGAAT 0 12 3.70 9.65E−05 3′ss Mel. 35282126- 35282104- GGGCTACATCCC GGGCTACATACC 35284762 35284762 CTTGGTTCTCTG ATCTGCCAGCAT TTAC (35) GACT (36) 584 chr22: chr22: TGCTCAGAGGTG TGCTCAGAGGTG 0 12 3.70 8.43E−07 3′ss Mel. 19948812- 19948812- CTTTGAAGCCCA CTTTGAAGATGC 19950181 19950049 TCCACAACCTGC CGGAGGCCCCGC TCAT (886) CTCT (887) 585 chr2: chr2: CAAGATAGATAT CAAGATAGATAT 0 12 3.70 3.94E−03 3′ss Mel. 170669034- 170669016- TATAGCAGGTGG TATAGCAGAACT 170671986 170671986 CTTTTGTTTTAC TCGATATGACCT AGAA (99) GCCA (100) 586 chr15: chr15: GCCTCACTGAGC GCCTCACTGAGC 2 37 3.66 8.44E−08 exon Mel. 25207356- 25207356- AACCAAGAGTAG AACCAAGAGTGT incl. 25212175 25213078 TGACTTGTCAGG CAGTTGTACCCG AGGA (144) AGGC (145) 587 chr11: chr11: CCACGGCCACGG CCACGGCCACGG 4 60 3.61 3.80E−03 3′ss Mel. 8704812- 8704812- CCGCATAGCTTT CCGCATAGGCAA 8705536 8705552 GTATTCCTGCAG GCACCGGAAGCA GCAA (888) CCCC (889) 588 chr11: chr11: CATGCCGGGGCC CATGCCGGGGCC 0 11 3.58 1.83E−02 3′ss Mel. 11988666- 11988645- AGAGGATGGCTC AGAGGATGCTCT 11989941 11989941 TTTCCACCTGTC GCACCCGGGACA TGCA (890) GTGA (891) 589 chr16: chr16: GGCGAAGCAAGA GGCGAAGCAAGA 0 11 3.58 1.88E−02 3′ss Mel. 19838459- 19838459- ACAAAAAGTATT ACAAAAAGTGAA 19843229 19867808 TTCTTCTAGGAT ATGCAAAATGGA GGAA (892) GGAC (893) 590 chr1: chr1: GGCTCCCATTCT GGCTCCCATTCT 0 11 3.58 2.42E−03 3′ss Mel. 155630724- 155630704- GGTTAAAGAGTG GGTTAAAGGCCA 155631097 155631097 TTCTCATTTCCA GTCTGCCATCCA ATAG (195) TCCA (196) 591 chr1: chr1: GAAGAACAGGAT GAAGAACAGGAT 0 11 3.58 1.74E−02 3′ss Mel. 219366593- 219366593- ATTAATAGTATG ATTAATAGGAGG 219383856 219383873 TTTTTGTTTTTA ATTCTCTATGGG GGAG (894) AGGA (895) 592 chr19: chr19: CAAGCAGGTCCA CAAGCAGGTCCA 0 10 3.46 2.28E−04 3′ss Mel. 5595521- 5595508- AAGAGAGATTTT AAGAGAGAAGCT 5598803 5598803 GGTAAACAGAGC CCAAGAGTCAGG TCCA (138) ATCG (139) 593 chr5: chr5: CAATTCAGTAGA AGGTCTTCCTGG 0 10 3.46 2.42E−02 5′ss Mel. 462644- 462422- TTCACCCTCAAC ACCTGGAGCAAC 464404 464404 ATCTGAATGAAT ATCTGAATGAAT TGAT (896) TGAT (897) 594 chr9: chr9: GGGAGATGGATA GGGAGATGGATA 3 41 3.39 1.97E−10 3′ss Mel. 35813153- 35813142- CCGACTTGCTCA CCGACTTGTGAT 35813262 35813262 ATTTCAGTGATC CAACGATGGGAA AACG (146) GCTG (147) 595 chr1: chr1: AGAGGGCACGGG AGAGGGCACGGG 2 29 3.32 1.42E−03 3′ss Mel. 205240383- 205240383- ACATCCAGCCCC ACATCCAGGAGG 205240923 205240940 TCTGCCCCTGCA CCGTGGAGTCCT GGAG (898) GCCT (899) 596 chr11: chr11: TTCTCCAGGACC TTCTCCAGGACC 0 9 3.32 6.24E−03 3′ss Mel. 125442465- 125442465- TTGCCAGACCTT TTGCCAGAGGAA 125445146 125445158 TTCTATAGGGAA TCAAAGACTCCA TCAA (150) TCTG (151) 597 chr11: chr11: GGATGACCGGGA GGATGACCGGGA 0 9 3.32 3.79E−04 3′ss Mel. 71939542- 71939542- TGCCTCAGTCAC TGCCTCAGATGG 71939690 71939770 TTTACAGCTGCA GGAGGATGAGAA TCGT (47) GCCC (48) 598 chr16: chr16: AGATGATTGAGG AGATGATTGAGG 0 9 3.32 1.06E−02 3′ss Mel. 70292147- 70292120- CAGCCAAGCTCT CAGCCAAGGCCG 70292882 70292882 TTTCTGTCTTCT TCTATACCCAGG TGGT (900) ATTG (901) 599 chr2: chr2: GAGGAGCCACAC GAGGAGCCACAC 0 9 3.32 2.20E−02 3′ss Mel. 220044485- 220044485- TCTGACAGATAC TCTGACAGTGAG 220044888 220044831 CTGGCTGAGAGC GGTGCGGGGTCA TGGC (107) GGCG (108) 600 chr3: chr3: GCTGCTCTCTTC GCTGCTCTCTTC 0 9 3.32 2.87E−06 3′ss Mel. 45043100- 45043100- AATACAAGTGCT AATACAAGGATA 45046767 45046782 TCTGCTTCCAGG CCAAGGGTTCGA ATAC (902) GTTT (903) 601 chr9: chr9: AATAGAACTTCC AATAGAACTTCC 7 76 3.27 4.47E−08 3′ss Mel. 101891382- 101891382- AACTACTGGCCC AACTACTGTAAA 101894778 101894790 TTTTTCAGTAAA GTCATCACCTGG GTCA (904) CCTT (905) 588 chr11: chr11: CATGCCGGGGCC CATGCCGGGGCC 0 11 3.58 1.83E−02 3′ss Mel. 11988666- 11988645- AGAGGATGGCTC AGAGGATGCTCT 11989941 11989941 TTTCCACCTGTC GCACCCGGGACA TGCA (890) GTGA (891) 589 chr16: chr16: GGCGAAGCAAGA GGCGAAGCAAGA 0 11 3.58 1.88E−02 3′ss Mel. 19838459- 19838459- ACAAAAAGTATT ACAAAAAGTGAA 19843229 19867808 TTCTTCTAGGAT ATGCAAAATGGA GGAA (892) GGAC (893) 590 chr1: chr1: GGCTCCCATTCT GGCTCCCATTCT 0 11 3.58 2.42E−03 3′ss Mel. 155630724- 155630704- GGTTAAAGAGTG GGTTAAAGGCCA 155631097 155631097 TTCTCATTTCCA GTCTGCCATCCA ATAG (195) TCCA (196) 591 chr1: chr1: GAAGAACAGGAT GAAGAACAGGAT 0 11 3.58 1.74E−02 3′ss Mel. 219366593- 219366593- ATTAATAGTATG ATTAATAGGAGG 219383856 219383873 TTTTTGTTTTTA ATTCTCTATGGG GGAG (894) AGGA (895) 592 chr19: chr19: CAAGCAGGTCCA CAAGCAGGTCCA 0 10 3.46 2.28E−04 3′ss Mel. 5595521- 5595508- AAGAGAGATTTT AAGAGAGAAGCT 5598803 5598803 GGTAAACAGAGC CCAAGAGTCAGG TCCA (138) ATCG (139) 593 chr5: chr5: CAATTCAGTAGA AGGTCTTCCTGG 0 10 3.46 2.42E−02 5′ss Mel. 462644- 462422- TTCACCCTCAAC ACCTGGAGCAAC 464404 464404 ATCTGAATGAAT ATCTGAATGAAT TGAT (896) TGAT (897) 594 chr9: chr9: GGGAGATGGATA GGGAGATGGATA 3 41 3.39 1.97E−10 3′ss Mel. 35813153- 35813142- CCGACTTGCTCA CCGACTTGTGAT 35813262 35813262 ATTTCAGTGATC CAACGATGGGAA AACG (146) GCTG (147) 595 chr1: chr1: AGAGGGCACGGG AGAGGGCACGGG 2 29 3.32 1.42E−03 3′ss Mel. 205240383- 205240383- ACATCCAGCCCC ACATCCAGGAGG 205240923 205240940 TCTGCCCCTGCA CCGTGGAGTCCT GGAG (898) GCCT (899) 596 chr11: chr11: TTCTCCAGGACC TTCTCCAGGACC 0 9 3.32 6.24E−03 3′ss Mel. 125442465- 125442465- TTGCCAGACCTT TTGCCAGAGGAA 125445146 125445158 TTCTATAGGGAA TCAAAGACTCCA TCAA (150) TCTG (151) 597 chr11: chr11: GGATGACCGGGA GGATGACCGGGA 0 9 3.32 3.79E−04 3′ss Mel. 71939542- 71939542- TGCCTCAGTCAC TGCCTCAGATGG 71939690 71939770 TTTACAGCTGCA GGAGGATGAGAA TCGT (47) GCCC (48) 598 chr16: chr16: AGATGATTGAGG AGATGATTGAGG 0 9 3.32 1.06E−02 3′ss Mel. 70292147- 70292120- CAGCCAAGCTCT CAGCCAAGGCCG 70292882 70292882 TTTCTGTCTTCT TCTATACCCAGG TGGT (900) ATTG (901) 599 chr2: chr2: GAGGAGCCACAC GAGGAGCCACAC 0 9 3.32 2.20E−02 3′ss Mel. 220044485- 220044485- TCTGACAGATAC TCTGACAGTGAG 220044888 220044831 CTGGCTGAGAGC GGTGCGGGGTCA TGGC (107) GGCG (108) 600 chr3: chr3: GCTGCTCTCTTC GCTGCTCTCTTC 0 9 3.32 2.87E−06 3′ss Mel. 45043100- 45043100- AATACAAGTGCT AATACAAGGATA 45046767 45046782 TCTGCTTCCAGG CCAAGGGTTCGA ATAC (902) GTTT (903) 601 chr9: chr9: AATAGAACTTCC AATAGAACTTCC 7 76 3.27 4.47E−08 3′ss Mel. 101891382- 101891382- AACTACTGGCCC AACTACTGTAAA 101894778 101894790 TTTTTCAGTAAA GTCATCACCTGG GTCA (904) CCTT (905) 602 chr17: chr17: CTATTTCACTCT CTATTTCACTCT 2 27 3.22 1.02E−05 3′ss Mel. 7131030- 7131102- CCCCCGAACCTA CCCCCGAAATGA 7131295 7131295 TCCAGGTTCCTC GCCCATCCAGCC CTCC (33) AATT (34) 603 chr17: chr17: TGTTACTGCAGT TGTTACTGCAGT 1 17 3.17 2.33E−03 3′ss Mel. 79556145- 79556145- GGCTACAGGTCT GGCTACAGGTGG 79563141 79563141 CTCTCTTGCAGG TCCTGACAACCA TGGT (906) AGTC (907) 604 chr13: chr13: ACATCACAAAGC ACATCACAAAGC 0 8 3.17 1.95E−03 3′ss Mel. 45841511- 45841511- AACCTGTGGGGT AACCTGTGGTGT 45857556 45857576 TTTGTTTTTGTT ACCTGAAGGAAA TTAG (908) TCTT (909) 605 chr14: chr14: GGTGCTGGCTGC GGTGCTGGCTGC 0 8 3.17 3.94E−03 3′ss Mel. 105176525- 105176525- CTGCGAAACCCT CTGCGAAAGCCT 105177255 105177273 GGCTGCCCCTGC GCTCACCAGCCG AGGC (910) CCAG (911) 606 chr16: chr16: CACCAAGCAGAG CACCAAGCAGAG 0 8 3.17 7.87E−04 3′ss Mel. 15129410- 15129410- GCTTCCAGTCTG GCTTCCAGGCCA 15129852 15129872 TCTGCCCTTTCT GAAGCCTTTTAA GTAG (216) AAGG (217) 607 chr17: chr17: CCTCTCTGCTCG CCTCTCTGCTCG 0 8 3.17 7.21E−08 3′ss Mel. 17062316- 17062316- AGAAGGAGTGTG AGAAGGAGCTGG 17064532 17064553 TGTCTTTTTGCC AGCAGAGCCAGA AACA (912) AGGA (913) 608 chr19: chr19: ATCACAACCGGA ATCACAACCGGA 0 8 3.17 1.45E−02 3′ss Mel. 15491444- 15491423- ACCGCAGGCTCC ACCGCAGGCTCA 15507960 15507960 TTCTGCCCTGCC TGATGGAGCAGT CGCA (661) CCAA (662) 609 chr3: chr3: CTGGAAGCTCAA CTGGAAGCTCAA 0 8 3.17 4.68E−04 3′ss Mel. 112724877- 112724851- GGTACTAGATTT GGTACTAGTTTG 112727017 112727017 TTCCTCTCTCTG CCAAAGAAACTA TCTT (914) GAGT (915) 610 chr1: chr1: CCCGAGCTCAGA CCCGAGCTCAGA 4 41 3.07 3.31E−04 3′ss Mel. 3548881- 3548902- GAGTAAATTCTC GAGTAAATATGA 3549961 3549961 CTTACAGACACT GATCGCCTCTGT GAAA (177) CCCA (178) 611 chr2: chr2: TATCCATTCCTG TATCCATTCCTG 1 15 3.00 3.44E−05 3′ss Mel. 178096758- 178096736- AGTTACAGTATA AGTTACAGTGTC 178097119 178097119 AACTTCCTTCTC TTAATATTGAAA ATGC (156) ATGA (157) 612 chr11: chr11: CGGCGATGACTC CGGCGATGACTC 0 7 3.00 2.48E−02 3′ss Mel. 62554999- 62554999- GGACCCAGCTTC GGACCCAGGGCT 62556481 62556494 TCTCCACAGGGC CCTTCAGTGGTA TCCT (916) GATG (917) 613 chr15: chr15: CCGCCAGGAGAA CCGCCAGGAGAA 0 7 3.00 9.38E−04 3′ss Mel. 41102168- 41102168- CAAGCCCATCCC CAAGCCCAAGTT 41102274 41102268 CTCACAGGCAGA AGTCCCCTCACA GATA (918) GGCA (919) 614 chr16: chr16: CAGCAGCAGCTC CAGCAGCAGCTC 0 7 3.00 9.09E−03 3′ss Mel. 48311390- 48311390- TGCTTGAGCTAC TGCTTGAGGTGT 48330007 48329925 TGCCAACACCAC TGGATCCTGAAC TGCT (920) AAAA (921) 615 chr2: chr2: AGACAAGGGATT AGACAAGGGATT 0 7 3.00 6.35E−04 3′ss Mel. 26437445- 26437430- GGTGGAAACATT GGTGGAAAAATT 26437921 26437921 TTATTTTACAGA GACAGCGTATGC ATTG (295) CATG (296) 616 chr3: chr3: GCACTTATGGTG GCACTTATGGTG 0 7 3.00 1.74E−07 3′ss Mel. 48638222- 48638273- GTGGCGTGAGTT GTGGCGTGCACC 48638407 48638407 TCCAGACCTTCA TGTCCAGCCCAC GCAT(922) TGGC (923) 617 chr19: chr19: GTGCTTGGAGCC GTGCTTGGAGCC 4 35 2.85 1.91E−07 3′ss Mel. 55776746- 55776757- CTGTGCAGACTT CTGTGCAGCCTG 55777253 55777253 TCCGCAGGGTGT GTGACAGACTTT GCGC (179) CCGC (180) 618 chr9: chr9: GTGGCTCCAGTA GACCTGCTCAAG 8 63 2.83 2.74E−02 5′ss Mel. 119414072- 119414072- TCAGAAAGAGAC TTCACTCAAGAC 119488049 II9449344 CACAGAGCTGGG CACAGAGCTGGG CAGC (924) CAGC (925) 619 chr10: chr10: TGTGGGCATGGA TGTGGGCATGGA 0 6 2.81 8.27E−08 3′ss Mel. 82264534- 82264534- GCGAAAAGTGCT GCGAAAAGGGTG 82266954 82266983 GCCCTGCTTTCT TGCTGTCCGACC CTGT (926) TCAC (927) 620 chr12: chr12: TTCCTCTTCCCC TTCCTCTTCCCC 0 6 2.81 4.32E−06 3′ss Mel. 56361953- 56361953- TCATCAAGTCCT TCATCAAGAGCT 56362539 56362561 CTCTTTCTCCTT ATCTGTTCCAGC TGTC (928) TGCT (929) 621 chr19: chr19: GGGGCACTGACA GGGGCACTGACA 0 6 2.81 2.67E−02 3′ss Mel. 50149459- 50149459- CGGCTACTAGCC CGGCTACTGTGT 50149761 50149782 TCTCTGGCCTCT TGGACATGGCCA TCCA (930) CGGA (931) 622 chr20: chr20: ACATGAAGGTGG ACATGAAGGTGG 0 6 2.81 1.25E−04 3′ss Mel. 34144042- 34144042- ACGGAGAGTTCT ACGGAGAGGTAC 34144761 34144743 CTGTGACCAGAC TGAGGACAAATC ATGA (250) AGTT (50) 623 chrX: chrX: TGACTCCGCTGC TGACTCCGCTGC 0 6 2.81 1.80E−02 3′ss Mel. 118923962- 118923974- TCGCCATGACTT TCGCCATGTCTT 118925536 118925536 TCAGGATTAAGC CTCACAAGACTT GATT (697) TCAG (698) 624 chr2: chr2: CCCCTGAGATGA CCCCTGAGATGA 3 25 2.70 6.46E−06 exon Mel. 27260570- 27260570- AGAAAGAGCTCC AGAAAGAGCTCC incl. 27260682 27261013 CTGTTGACAGCT TGAGCAGCCTGA GCCT (183) CTGA (184) 625 chr2: chr2: AGGCTGTAGCAG AGGCTGTAGCAG 1 12 2.70 2.24E−02 3′ss Mel. 99225189- 99225189- GACTCCAGGGTT GACTCCAGGAAG 99226105 99226218 GGGAAGAACATG ATGTTACCGAGT GAAA (932) ACTT (933) 626 chr8: chr8: CCGAGGATGCTA CCGAGGATGCTA 4 30 2.63 6.42E−03 3′ss Mel. 133811106- 133811106- AGGGGCAGTTTC AGGGGCAGGATT 133811328 133816063 TGTTCCAGGTGA GGATAGCTTTAG AATC (934) TCAA (935) 627 chr21: chr21: GCCTCCCGGTCC GCCTCCCGGTCC 4 29 2.58 9.60E−04 3′ss Mel. 46935066- 46936054- GCAAGCAGAATG GCAAGCAGTTCC 46945730 46945730 AAGAACTGCATG AGTTATACTCCG TGGC (936) TGTA (937) 628 chr17: chr17: TCGTAACAGGGG CTGTGACGGGTG 3 23 2.58 1.22E−02 exon Mel. 27210249- 27210249- TTGCACAGGTGA TCGCCCAGGTGA skip 27212874 27211242 AGATCATGACGG AGATCATGACGG AGAA (938) AGAA (939) 629 chr6: chr6: GTTTGGGGAAGT GTTTGGGGAAGT 1 11 2.58 2.07E−05 exon Mel. 112020873- 112017659- ATGGATGGAGAA ATGGATGGGTAC incl. 112021306 112021306 AGCTGATGGTTT CTGGAATGGAAA GTGT (940) CACA (941) 630 chr6: chr6: TAACTAATCCTT CAGCCTACCAGA 1 11 2.58 4.06E−02 5′ss Mel. 39854223- 39851845- CTCAGCAGAAAG GGCACCAGAAAG 39855261 39855261 AGCTGGGCTCCA AGCTGGGCTCCA CTGA (942) CTGA (943) 631 chr11: chr11: AGTCCAGCCCCA AGTCCAGCCCCA 0 5 2.58 9.35E−03 3′ss Mel. 64900740- 64900723- GCATGGCACCTC GCATGGCAGTCC 64900940 64900940 TCCCCACTCCTA TGTACATCCAGG GGTC (136) CCTT (137) 632 chr16: chr16: GGATCCTTCACC GGATCCTTCACC 0 5 2.58 1.87E−03 3′ss Mel. 1402307- 1402307- CGTGTCTGTCTT CGTGTCTGGACC 1411686 1411743 TGCAGACAGGTT CGTGCATCTCTT CTGT (85) CCGA (86) 633 chr17: chr17: GCATCTCAGCCC GCATCTCAGCCC 0 5 2.58 1.16E−05 3′ss Mel. 16344444- 16344444- AAGAGAAGTTTC AAGAGAAGGTTA 16344670 16344681 TTTGCAGGTTAT TATTCCCAGAGG ATTC (287) ATGT (288) 634 chr1: chr1: CTACACAGAGCT CTACACAGAGCT 0 5 2.58 2.48E−06 3′ss Mel. 32096333- 32096443- GCAGCAAGGTGT GCAGCAAGCTCT 32098095 32098095 GCACCCAGCTGC GTCCCAAATGGG AGGT (291) CTAC (292) 635 chr22: chr22: CCTGCGCAACTG CCTGCGCAACTG 0 5 2.58 1.56E−04 3′ss Mel. 19164146- 19164206- GTACCGAGGCGC GTACCGAGGGGA 19164358 19164358 AGCCAGTGTCTT CAACCCCAACAA TGGA (944) GCCC (945) 636 chr3: chr3: ATAAAAATTGCT ATAAAAATTGCT 0 5 2.58 2.28E−03 3′ss Mel. 131181737- 131181719- TAGTAAAGATTT TAGTAAAGGTCA 131186934 131186934 TTGCCTTCTCTC AAGATTCTAAAC AGGT (946) TGCC (947) 637 chrX chr8: TGAGTTCATGGA TGAGTTCATGGA 0 5 2.58 3.48E−02 3′ss Mel. 98817692- 98817692- TGATGCCAAAAT TGATGCCAACAT 98827531 98827555 TCTTTTTAATCT GTGCATTGCCAT TTCG (948) TGCG (949) 638 chrX: chrX: AGAGTTGAAAAA AGAGTTGAAAAA 0 5 2.58 4.97E−03 3′ss Mel. 24091380- 24091380- CACTGGCGTCTC CACTGGCGTTTA 24092454 24094838 CTTTTCAGGAAT ATTGGTTGGGGT CACA (950) CAGA (951) 639 chr12: chr12: GGCCAGCCCCCT GGCCAGCCCCCT 8 51 2.53 3.07E−09 3′ss Mel. 120934019- 120934019- TCTCCACGGCCT TCTCCACGGTAA 120934204 120934218 TGCCCACTAGGT CCATGTGCGACC AACC (206) GAAA (207) 640 chr9: chr9: CACCACGCCGAG CACCACGCCGAG 3 21 2.46 2.87E−02 3′ss Mel. 125023777- 125023787- GCCACGAGACAT GCCACGAGTATT 125026993 125026993 TGATGGAAGCAG TCATAGACATTG AAAC (142) ATGG (143) 641 chr1O: chr1O: TGGGGCCACAAA TGGGGCCACAAA 4 24 2.32 1.77E−02 exon Mel. 74994698- 74994698- GACAGATGCTGG GACAGATGAAAC skip 74999069 74994950 ATACACAGTATC CCCATGGCGACT GTCG (952) CTAG (953) 642 chr1: chr1: CTTGCCTTCCCA CTTGCCTTCCCA 1 9 2.32 1.49E−04 3′ss Mel. 154246074- 154246074- TCCTCCTGCAAA TCCTCCTGAACT 154246225 154246249 CACCTGCCACCT TCCAGGTCCTGA TTCT (289) GTCA (290) 643 chr11: chr11: GGGGACAGTGAA GGGGACAGTGAA 0 4 2.32 1.19E−05 3′ss Mel. 57100545- 57100623- ATTTGGTGGCAA ATTTGGTGGGCA 57100908 57100908 GAATGAGGTGAC GCTGCTTTCCTT ACTG (103) TGAC (104) 644 chr16: chr16: GAACTGGCACCG GAACTGGCACCG 0 4 2.32 1.03E−03 3′ss Mel. 313774- 313774- ACAGACAGTGTC ACAGACAGATCC 313996 314014 CCCTCCCTCCCC TGTTTCTGGACC AGAT (244) TTGG (245) 645 chr17: chr17: AACATGGAATCA AACATGGAATCA 0 4 2.32 1.03E−03 3′ss Mel. 34147441- 34147441- TCAGGAAGTTCT TCAGGAAGCCAA 34149625 34149643 CCATTTCTATTT GGTGGAAGAGCA AGCC (954) CCTT (955) 646 chr1: chr1: CGTGCGTGTGTG CTTAGGAAAGAC 0 4 2.32 2.87E−02 5′ss Mel. 1480382- 1480382- TGCTCTTGCTAT AAAGAACTCTAT 1497319 1500152 ACACAGAATGGG ACACAGAATGGG ATTT (956) ATTT (957) 647 chr22: chr22: CCCAGCCTGCTG CCCAGCCTGCTG 0 4 2.32 3.33E−02 3′ss Mel. 24108483- 24108462- TCCAGCAGCCTC TCCAGCAGGCCC 24109560 24109560 TTGCACTGTACC CCACCCCCGCTG CCCA (958) CCCC (959) 648 chr22: chr22: ACCCAAGGCTCG ACCCAAGGCTCG 0 4 2.32 5.75E−03 3′ss Mel. 44559810- 44559810- TCCTGAAGTTTC TCCTGAAGACGT 44564460 44564481 TCTGTTTCCTTC GGTTAACTTGGA TGCA (960) CCTC (961) 649 chr5: chr5: AGATTGAAGCTA AGATTGAAGCTA 0 4 2.32 1.38E−03 3′ss Mel. 132439718- 132439718- AAATTAAGTTTT AAATTAAGGAGC 132439902 132439924 CTGTCTTACCCA TGACAAGTACTT TTCC (348) GTAG (349) 650 chr5: chr5: GAACCCGGTGGT GAACCCGGTGGT 0 4 2.32 5.33E−04 3′ss Mel. 175815974- 175815974- ACCCATAGTTGC ACCCATAGGTTG 175816311 175816331 TTTGTCCCCTCC CCTGGCCACGGC TCAG (962) GGCC (963) 651 ch17: chr7: AATGGAAGTACC AATGGAAGTACC 0 4 2.32 7.50E−03 3′ss Mel. 74131270- 74131270- AGCAGAAGAATT AGCAGAAGATTC 74133179 74133197 TTATTTTTTTCA TACTCAACATGT AGAT (964) CCCT (965) 652 chr20: chr20: GGCAGCTGTTAG GGCAGCTGTTAG 7 37 2.25 4.91E−02 exon Mel. 57227143- 57227143- CCGAGCAAGAGC CCGAGCAACTTG incl. 57234678 57242545 TGGACGAGGTAT CTGATGACCGTA TGTG (966) TGGC (967) 653 chr16: chr16: GAGATTCTGAAG GAGATTCTGAAG 3 18 2.25 1.03E−03 3′ss Mel. 54954250- 54954322- ATAAGGAGTTCT ATAAGGAGGTAA 54957496 54957496 CTTGTAGGATGC AACCTGTTTAGA CACT (313) AATT (314) 654 chrX: chrX: AAAAGAAACTGA AAAAGAAACTGA 14 70 2.24 5.98E−06 3′ss Mel. 129771378- 129771384- GGAATCAGTATC GGAATCAGCCTT 129790554 129790554 ACAGGCAGAAGC AGTATCACAGGC TCTG (303) AGAA (304) 655 chr13: chr13: GTTTAGAAATGG GTTTAGAAATGG 18 88 2.23 1.12E−04 3′ss Mel. 45911538- 45911523- AAAAATGTTTTT AAAAATGTTAAC 45912794 45912794 TGCTTTTACAGT AAATGTGGCAAT AACA (968) TATT (969) 656 chr2: chr2: CCAAGAGACAGC CCCCTGAGATGA 5 27 2.22 4.64E−05 exon Mel. 27260760- 27260570- ACATTCAGCTCC AGAAAGAGCTCC incl. 27261013 27261013 TGAGCAGCCTGA TGAGCAGCCTGA CTGA (315) CTGA (184) 657 chr1: chr1: TTGGAAGCGAAT TTGGAAGCGAAT 1 8 2.17 6.85E−03 3′ss Mel. 23398690- 23398690- CCCCCAAGTCCT CCCCCAAGTGAT 23399766 23399784 TTGTTCTTTTGC GTATATCTCTCA AGTG (210) TCAA (211) 658 chr6: chr6: AGGATGTGGCTG AGGATGTGGCTG 1 8 2.17 2.70E−05 3′ss Mel. 31602334- 31602334- GCACAGAAGTGT GCACAGAAATGA 31602574 31602529 CATCAGGTCCCT GTCAGTCTGACA GCAG (148) GTGG (149) 659 chr3: chr3: AAATCTCGTGGA AAATCTCGTGGA 7 33 2.09 4.05E−02 3′ss Mel. 16310782- 16310782- CTTCTAAGTTTT CTTCTAAGAAAG 16312435 16312451 CTGTTTGCCCAG CGCCATGGCCTG AAAG (970) TGCT (971) 660 chr11: chr11: AGTTCCGGGGCT AGTTCCGGGGCT 0 3 2.00 2.75E−02 3′ss Mel. 68838888- 68838888- ACCTGATGCCTT ACCTGATGAAAT 68839375 68839390 CCTCTTTGCAGA CTCTCCAGACCT AATC (972) CGCT (973) 661 chr12: chr12: GGCACCCCAAAA GGCACCCCAAAA 0 3 2.00 1.12E−02 3′ss Mel. 58109976- 58109976- GATGGCAGATCA GATGGCAGGTGC 58110164 58110194 GTCTCTCCCTGT GAGCCCGACCAA TCTC (285) GGAT (286) 662 chr1: chr1: AAGAAGGAATCC AAGAAGGAATCC 0 3 2.00 7.34E−03 3′ss Mel. 32377442- 32377427- ACGTTCTAGTCA ACGTTCTAGATT 32381495 32381495 TTTCTTTTCAGG GGCCATTTGATG ATTG (974) ATGG (975) 663 chr22: chr22: CGCTGGCACCAT CGCTGGCACCAT 0 3 2.00 2.55E−02 3′ss Mel. 36627471- 36627512- GAACCCAGGACC GAACCCAGAGAG 36629198 36629198 AAGTGAGCAGAG CAGTATCTTTAT AGAA (976) TGAG (200) 664 chr3: chr3: GCAACCAGTTTG GCAACCAGTTTG 0 3 2.00 3.20E−03 3′ss Mel. 49395199- 49395180- GGCATCAGCTGC GGCATCAGGAGA 49395459 49395459 CCTTCTCTCCTG ACGCCAAGAACG TAGG (342) AAGA (343) 665 chr6: chr6: AGCCCCTGCTTG AGCCCCTGCTTG 0 3 2.00 4.68E−04 3′ss Mel. 170844509- 170844493- ACAACCAGTTTC ACAACCAGGTTG 170846321 170846321 ATGTCCCACCAG GTTTTAAGAACA GTTG (977) TGCA (978) 666 chr9: chr9: CCAAGGACTGCA CCAAGGACTGCA 0 3 2.00 4.46E−02 3′ss Mel. 139837449- 139837395- CTGTGAAGGCCC CTGTGAAGATCT 139837800 139837800 CCGCCCCGCGAC GGAGCAACGACC CTGG (175) TGAC (176) 667 chr10: chr10: TTGGCTGTAGGA TTGGCTGTAGGA 8 34 1.96 2.70E−05 exon Mel. 103904064- 103904064- AACTCAGGGTCC AACTCAGGCGGC skip 103908128 103904776 AGCTGTAGTTCC GTTGACATTCCC TCTG (979) CAGG (980) 668 chr17: chr17: TGTATCTCCGAC TGTATCTCCGAC 6 26 1.95 3.79E−02 exon Mel. 27212965- 27211333- ACTCAGAGACTG ACTCAGAGGATT incl. 27215962 27215962 TCTCTGGAGGTT TCCCTAGAGATT ATGA (981) ATGA (982) 669 chrX: chrX: AGGCTGATCTAC AGGCTGATCTAC 2 10 1.87 5.30E−03 3′ss Mel. 15849691- 15845495- TGCAGGAGCCAC TGCAGGAGGAAG 15863501 15863501 GTCATGAATATT CTGAAACCCCAC TTAA (983) GTAG (984) 670 chr2: chr2: GGAAATGGGACA GGAAATGGGACA 14 52 1.82 4.43E−06 3′ss Mel. 230657846- 230657861- GGAGGCAGAGGA GGAGGCAGCTTT 230659894 230659894 TCACAGGCTTTA TCTCTCAACAGA AAAT (387) GGAT (388) 671 chr5: chr5: GCTCAGCCCCCT TGACCCTGCAGC 5 20 1.81 2.74E−03 exon Mel. 141694720- 141694720- CCCCACAGGGCC TCCTCAAAGGCC incl. 141699308 141704408 CCTAGAAGCCTG CCTAGAAGCCTG TTTC (985) TTTC (986) 672 chr19: chr19: GCCGACCCGCCT GCCGACCCGCCT 3 13 1.81 4.16E−03 3′ss Mel. 3542975- 3544730- GCGACGCTCTTT GCGACGCTGGGA 3544806 3544806 TCTTGCCTGGAG CCGTGATGCCCG AAGA (987) GCCC (988) 673 chr3: chr3: TGCGGAGACCCC TGCGGAGACCCC 1 6 1.81 2.67E−02 exon Mel. 58417711- 58419411- TTCGGGAGGTGA TTCGGGAGGTCT skip 58419494 58419494 CAGTTCGTGATG CCGGGCTGCTGA CTAT (989) AGAG (990) 674 chr6: chr6: CTATCAGTAGGT GCATTGATGTGG 1 6 1.81 2.71E−03 exon Mel. 108370622- 108370622- TTTTAGAGATGA AAGATGCAATGA incl. 108370735 108372234 ACATCACTCGAA ACATCACTCGAA AACT (991) AACT (992) 675 chr6: chr6: GCATTGATGTGG GCATTGATGTGG 1 6 1.81 1.84E−03 exon Mel. 108370787- 108370622- AAGATGCAGTTT AAGATGCAATGA incl. 108372234 108372234 TTTTCCTGGCAG ACATCACTCGAA AAGA (993) AACT (992) 676 chr6: chr6: CAGTGGGCGGAT CAGTGGGCGGAT 1 6 1.81 1.04E−02 3′ss Mel. 166779550- 166779594- GACATTTGGTAC GACATTTGCCCT 166780282 166780282 AGCCTCGGAACT CTGTTGCTATTC GGCT (994) TTTG (995) 677 chr7: chr7: GGTGTCCATGGC GGTGTCCATGGC 1 6 1.81 4.73E−02 exon Mel. 128033792- 128033082- CTGCACTCCTAT CTGCACTCTTAC incl. 128034331 128034331 ACCTTTCTGCCG GAAAAGCGGCTG TGTA (996) TACT (997) 678 chr6: chr6: ACTGGGAAGTTC ACTGGGAAGTTC 10 37 1.79 1.30E−02 exon Mel. 136597127- 136597646- TTAAAAAGTCCC TTAAAAAGGTTC skip 136599002 136599002 CCTCTACACAAG ACAGATGAAGAG AATC (998) TCTA (999) 679 chr16: chr16: GAGATTCTGAAG GAGATTCTGAAG 20 69 1.74 1.28E−05 3′ss Mel. 54954239- 54954322- ATAAGGAGGATG ATAAGGAGGTAA 54957496 54957496 CCACTGGAAATG AACCTGTTTAGA TTGA (322) AATT (314) 680 chr4: chr4: GCTGAGCGGGGC TCCAACAAGCAC 20 69 1.74 4.13E−05 exon Mel. 17806394- 17806394- GACCCGAGTCTT CTCTGAAGTCTT skip 17812069 17806729 CTCATTCACAGG CTCATTCACAGG TTAA (1000) TTAA (832) 681 chr19: chr19: AGTGGCAGTGGC AGTGGCAGTGGC 8 29 1.74 8.03E−04 3′ss Mel. 6731065- 6731122- TGTACCAGCCCA TGTACCAGCTCT 6731209 6731209 CAGGAAACAACC TGGTGGAGGGCT CGTA (311) CCAC (312) 682 chr16: chr16: TGTTCCACCTCC TGTTCCACCTCC 6 22 1.72 2.96E−02 3′ss Mel. 28842393- 28842393- TCCTGCAGCTCC TCCTGCAGTGGG 28843507 28843525 CCCTTTTCTTCC CCGGATGTATCC AGTG (1001) CCCG (1002) 683 chr3: chr3: ACCCATGAGAAT CTGGCCCCTGAG 8 28 1.69 8.95E−03 exon Mel. 50615004- 50616357- GCTCAGAGCTAT ATCCGCAGCTAT skip 50617274 50617274 GAAGACCCCGCG GAAGACCCCGCG GCCC (1003) GCCC (1004) 684 chr11: chr11: CAAGCTCGAGTC CAAGCTCGAGTC 4 15 1.68 8.31E−03 exon Mel. 772521- 773629- CATCGATGAACC CATCGATGGTGC skip 774007 774 (X)7 CATCTGCGCCGT CCGGTACCATGC CGGC (1005) CCTC (1006) 685 chr2: chr2: CTTCACTGTCAC CTTCACTGTCAC 9 30 1.63 2.25E−02 3′ss Mel. 220424219- 220426730- CGTCACAGAACC CGTCACAGAGTC 220427123 220427123 CCCAGTGCGGAT TTACCAAAGTCA CATA (1007) GGAC (1008) 686 chr3: chr3: GTCTTCCAATGG GTCTTCCAATGG 10 33 1.63 1.04E−02 3′ss Mel. 148759467- 148759455- CCCCTCAGCCTT CCCCTCAGGAAA 148759952 148759952 TTCTCTAGGAAA TGATACACCTGA TGAT (234) AGAA (235) 687 chr5: chr5: AGAAACAGAAAC AGAAACAGAAAC 5 17 1.58 1.55E−02 exon Mel. 34945908- 34945908- CAGCACAGGATG CAGCACAGAATT incl. 34949647 34950274 TACCTGGCAAAG ATGATGACAATT ATTC (1009) TCAA (1010) 688 ch16: chr6: TTCTGCATCTGT AAAGGAGTGCTT 2 8 1.58 1.45E−02 exon Mel. 158589427- 158591570- GGGCCGAGTGAT ATAGAATGTGAT skip 158613008 158613008 CCTGCCATGAAG CCTGCCATGAAG CAGT (1011) CAGT (1012) 689 chr14: chr14: AGGATCGGCAAC CTGGGATAAGAG 1 5 1.58 1.98E−02 exon Mel. 23495584- 23495584- ATGGCAAGGCCT AGGCCCTGGCCT incl. 23496953 23502576 CTACTACGTGGA CTACTACGTGGA CAGT (1013) CAGT (1014) 690 chr6: chr6: GTTCAGGACACA GGGAGGGAGAGA 1 5 1.58 1.23E−02 exon Mel. 33669197- 33669197- ATAAGCAGGTTG ATACCCAGGTTG incl. 33678471 33679325 CAGAGCCTGAGG CAGAGCCTGAGG CCTG (1015) CCTG (1016) 691 chr10: chr10: TACCCGGATGAT TACCCGGATGAT 0 2 1.58 2.58E−04 3′ss Mel. 102286851- 102286831- GGCATGGGAAGT GGCATGGGGTAT 102289136 102289136 TCTTGCTGTCTT GGCGACTACCCG TCAG (1017) AAGC (1018) 692 chr11: chr11: GACATATGAGTC GACATATGAGTC 0 2 1.58 2.45E−02 3′ss Mel. 66333872- 66333875- AAAGGAAGCCCG AAAGGAAGAAGC 66334716 66334716 GTGGCGCCTGTC CCGGTGGCGCCT CGTC (1019) GTCC (1020) 693 chr11: chr11: CGGATCAACTTC CGGATCAACTTC 0 2 1.58 2.65E−03 3′ss Mel. 8705628- 8705628- GACAAATAGTGG GACAAATACCAC 8706243 8706264 TTGTTACCTCTT CCAGGCTACTTT CCTA (1021) GGGA (1022) 694 chr12: chr12: TTATAGGCGTGA TTATAGGCGTGA 0 2 1.58 1.03E−03 3′ss Mel. 53421972- 53421972- TGATAGAGTTTC TGATAGAGGTCC 53427574 53427589 ATTTAACTTAGG CCCCCAAAGACC TCCC (1023) CAAA (1024) 695 chr15: chr15: TGGAAATATTTC GCCTCACTGAGC 0 2 1.58 7.87E−03 exon Mel. 25212387- 25207356- TAGACTTGGTGT AACCAAGAGTGT incl. 25213078 25213078 CAGTTGTACCCG CAGTTGTACCCG AGGC (1025) AGGC (145) 696 chr1: chr1: TCGGCCCAGAAG CTTAGGAAAGAC 0 2 1.58 4.66E−02 5′ss Mel. 1480382- 1480382- AACCCCGCCTAT AAAGAACTCTAT 1497338 1500152 ACACAGAATGGG ACACAGAATGGG ATTT (1026) ATTT (957) 697 chr5: chr5: TCTATATCCCCT TCTATATCCCCT 0 2 1.58 1.26E−04 3′ss Mel. 177576859- 177576839- CTAAGACGCACT CTAAGACGGACC 177577888 177577888 TCTTTCCCCTCT TGGGTGCAGCCG GTAG (299) CAGG (300) 698 chr6: chr6: GCTGAAGGGAAA GCTGAAGGGAAA 0 2 1.58 4.68E−02 3′ss Mel. 42905945- 42905945- AGACACCAAAAC AGACACCAGTTG 42911535 42906305 ACAAACAGCAGA CCTGGCAGAGCA ATGG (1027) GTGG (1028) 699 chr17: chr17: CATCATCAAGTT CATCATCAAGTT 5 16 1.5 1.74E−04 intron Mel. 2282497- 2282497- TTTCAATGACGA TTTCAATGAACG reten- 2282499 2282725 GCTGGTCCAGCC TGCTGAGCATCA tion ATCC (1029) CGAT (1030) 700 chr8: chr8: GAGGGCCTGCTC ACATGCTTCAAA 23 66 1.48 1.49E−03 exon Mel. 74601048- 74601048- ATTCAAAGATGT TAAATCAGATGT incl. 74621266 74650518 TCTCAGTGCAGC TCTCAGTGCAGC TGAG (1031) TGAG (1032) 701 chr10: chr10: CTGAGGCTAATG CTGAGGCTAATG 14 40 1.45 2.13E−02 3′ss Mel. 35495979- 35495979- AAAAACAGGGAA AAAAACAGGGAA 35500583 35500181 GCTGCCAAAGAA GCTGCCCGGGAG TGTC (1033) TGTC (1034) 702 chr3: chr3: CGGCTGGGACTC CGGCTGGGACTC 12 34 1.43 1.81E−02 3′ss Mel. 119180951- 119180995- TTCCATGCGTGG TTCCATGCAGTT 119182182 119182182 CACTGGAAGCAG GAAACTGGTTGA ACTG (1035) CAAC (1036) 703 chr4: chr4: AGTGAATGTAGT AGTGAATGTAGT 17 47 1.42 2.45E−02 exon Mel. 169919436- 169911479- TGCACCAGTGAC TGCACCAGGATT incl. 169923221 169923221 AATACTTGTATG TGTACACACAGA GAGT (1037) TATG (1038) 704 chr17: chr17: ATTCACACAGAG TGAGGATCAATC 2 7 1.42 1.30E−02 exon Mel. 55074416- 55075859- CCACCTAGGCCA CTGGGGAGGCCA skip 55078215 55078215 GGCTACCAACGT GGCTACCAACGT CTTT (1039) CTTT (1040) 705 chrX: chrX: AGAAACCTTGAA AGAAACCTTGAA 7 20 1.39 3.40E−02 exon Mel. 2310515- 2209644- CGACAAAGAGAC CGACAAAGTGGA incl. 2326785 2326785 GTGAGTCTTGCT ATTTTTATACTG GTGT (496) TGAC (495) 706 chrY: chrY: AGAAACCTTGAA AGAAACCTTGAA 7 20 1.39 3.40E−02 exon Mel. 2260515- 2159644- CGACAAAGAGAC CGACAAAGTGGA incl. 2276785 2276785 GTGAGTCTTGCT ATTTTTATACTG GTGT (496) TGAC (495) 707 chr5: chr5: TGGAAAAGTATA TGGAAAAGTATA 4 12 1.38 2.71E−02 exon Mel. 54456224- 54456224- AAGGCAAAATTC AAGGCAAAGTTT skip 54459882 54456821 TTCAAAGAAGGA CACTAGTTGTAA ACCA (1041) ACGT (1042) 708 chr15: chr15: ATACTAAGAACA ATACTAAGAACA 19 50 1.35 2.54E−02 exon Mel. 76146828- 76146828- ACAATTTGAATG ACAATTTGCTTC skip 76161291 76152218 GGACAACAGAAG GTCAGCAATTGA AAGT (1043) AGTG (1044) 709 chr8: chr8: TGGCCTTGACCT TGGCCTTGACCT 7 19 1.32 3.77E−02 3′ss Mel. 38270113- 38271322- CCAACCAGGTCC CCAACCAGGAGT 38271435 38271435 TGCACCCAGACC ACCTGGACCTGT TCAC (1045) CCAT (1046) 710 chr1: chr1: GAAGGCAGCTGA GAAGGCAGCTGA 3 9 1.32 1.42E−02 3′ss Mel. 11131045- 11131030- GCAAACAGTTCT GCAAACAGCTGC 11132143 11132143 CTCCCTTGCAGC CCGGGAACAGGC TGCC (393) AAAG (394) 711 chr11: chr11: TCCTTGAACACT TCCTTGAACACT 1 4 1.32 2.52E−02 exon Mel. 62556898- 62556898- ACAATTAGACCT ACAATTAGCTGT skip 62557357 62557072 cttcttgggtga TCTGAAGCCCAG ATTT (1047) AAAA (1048) exon 712 chr14: chr14: ACACCATTGAGG ACACCATTGAGG 1 4 1.32 1.92E−02 skip Mel. 69349309- 69349772- AGATCCAGGTGC AGATCCAGGGAC 69350884 69350884 GGCAGCTGGTGC TGACCACAGCCC CTCG (1049) ATGA (1050) 713 chr1: chr1: CCCATGTATAAG CCCATGTATAAG 1 4 1.32 2.77E−02 3′ss Mel. 155227125- 155227177- GCTTTCCGGATG GCTTTCCGGAGT 155227288 155227288 TGCTCTTTGTCC GACAGTTCATTC TCCA (1051) AATT (1052) 714 chr20: chr20: CTCCCAGTGCTG GAGCTGCCACGG 1 4 1.32 2.02E−02 exon Mel. 25281520- 25281520- TATATCCCGGAA ATACTGAGGGAA incl. 25281967 25282854 TTCCTGGGGAAG TTCCTGGGGAAG TCGG (1053) TCGG (1054) 715 Chr7: chr7: GGATGCGCGTCT AGCCGCAGAGCA 1 4 1.32 4.91E−02 exon Mel. 142962185- 142962389- GGTCAAGGGCTG TCCTGGCGGCTG skip 142964709 142964709 CAGAGAAGGCTG CAGAGAAGGCTG GTAT (1055) GTAT (1056) 716 chr8: chr8: ACATGCTTCAAA ACATGCTTCAAA 24 61 1.31 1.74E−02 exon Mel. 74621397- 74601048- TAAATCAGCTTC TAAATCAGATGT incl. 74650518 74650518 TCTCCAAGATAA TCTCAGTGCAGC AATG (1057) TGAG (1032) 717 chr15: chr15: AACAAAGAAATA CTGAGTCTTTAT 16 41 1.3 1.66E−03 exon Mel. 49309825- 49309825- ATTCACAGGATG ATTTTGAGGATG skip 49319561 49311614 AAGATGGGTTTC AAGATGGGTTTC AAGA (1058) AAGA (1059) 718 chrX: chrX: TAGCCACCACTG GGGAAAAGTCTT 11 28 1.27 1.07E−02 exon Mel. 148582568- 148582568- TGTGCCAGGGAT TCACCCTGGGAT incl. 148583604 148584841 ATCTTCTAACCA ATCTTCTAACCA TACC (1060) TACC (1061) 719 chr12: chr12: CCTACCAGCCAC CCTACCAGCCAC 4 11 1.26 2.42E−02 3′ss Mel. 49918679- 49918679- TTCGGGAGGTAT TTCGGGAGGTAT 49919860 49919726 CAGAGTGCTCCA TGCCAGGGAACA TCTC (1062) GACG (1063) 720 chr1: chr1: GTCCCGGCTTCC GTCCCGGCTTCC 4 11 1.26 2.67E−02 exon Mel. 46654652- 46655029- CCCTACTCGCCT CCCTACTCAGTG skip 46655129 46655129 GGCTCAGAATCT AAGAAGCCACCC AACC (1064) TCAG (1065) 721 chr3: chr3: CTTAAGCATATA CTTAAGCATATA 28 68 1.25 2.24E−02 exon Mel. 105397415- 105400454- TTTAAAGGGTGA TTTAAAGGGAGA skip 105400567 105400567 AGATGCTTTTGA TGTTTTTGATTC TGCC (1066) AGCC (1067) 722 chr3: chr3: CAGGAACAAGTA CAGGAACAAGTA 2 6 1.22 4.97E−02 exon Mel. 10023431- 10019130- TCTGACAGAAAA TCTGACAGTCAA incl. 10028190 10028190 TATCTTTCAGGC GTCCTAATTCGA CTGG (1068) AGCA (1069) 723 chr4: chr4: GAAGTTCTGAGG GAAGTTCTGAGG 2 6 1.22 1.07E−02 3′ss Mel. 88898249- 88898249- AAAAGCAGAATG AAAAGCAGCTTT 88901544 88901197 CTGTGTCCTCTG ACAACAAATACC AAGA (1070) CAGA (1071) 724 chr7: chr7: ATCTCCCTCTTG ATCTCCCTCTTG 2 6 1.22 1.94E−03 3′ss Mel. 23313233- 23313233- GTGTACAAATTG GTGTACAAAAAA 23313672 23313683 TTTTCAGAAAAC CACAAGGAATAC ACAA (1072) AACC (1073) 725 chr1: chr1: TGCGAGTACTGC TGCGAGTACTGC 6 15 1.19 3.00E−03 exon Mel. 214454770- 214454770- TTCACCAGAAAG TTCACCAGGAAA skip 214488104 214478529 AAGATTGGCCCA GAAGGATTGTCC TGCA (1074) AAAT (1075) 726 chr15: chr15: TCCAGAAAGTGA TCCAGAAAGTGA 15 35 1.17 2.02E−04 exon Mel. 101826006- 101826498- AACTAAAATTTT AACTAAAAGAGC skip 101827112 101827112 AATCCAGGTGCT GTCAGGAAGCAG GGTT (1076) AGAA (1077) 727 chr15: chr15: ACTCAGATGCCG ACTCAGATGCCG 39 88 1.15 2.54E−04 3′ss Mel. 74326871- 74326871- AAAACTCGCCCT AAAACTCGTGCA 74327483 74327512 CAGTCTGAGGTT TGGAGCCCATGG CTGT (748) AGAC (749) 728 chrX: chrX: AGATTCTACAGA AGATTCTACAGA 17 39 1.15 2.23E−02 exon Mel. 15706981- 15706981- TAAATCAGATTT TAAATCAGCTGC skip 15720904 15711085 CGGAAACTTCTG ACTTAGTGCATT GCAG (1078) GGAA (1079) 729 chr3: chr3: TGGCTGGCTTCA TGGCTGGCTTCA 40 90 1.15 1.67E−02 exon Mel. 183703166- 183700795- GTGGACCAAATT GTGGACCAGCCT incl. 183705557 183705557 TTCAGGATGGCT TCATGGTGAAAC GTAT (1080) ACCT (1081) 730 chr16: chr16: CCCTGCTCATCA CCCTGCTCATCA 19 40 1.04 9.38E−04 exon Mel. 684797- 684956- CCTACGGGGAAC CCTACGGGCCCT skip 685280 685280 CCAGAATGGGGG ATGCCATCAATG CTTC (1082) GGAA (194) 731 chrX: chrX: CAAACACCTCTT CAAACACCTCTT 11 23 1.00 2.44E−04 exon Mel. 123224614- 123224614- GATTATAACACG GATTATAATCGG incl. 123224703 123227867 CAGGTAACATGG CGTGGCACAAGC ATGT (468) CTAA (457) 732 chr20: chr20: GGCAGCCACCAC TGATAATTGGGC 10 21 1.00 2.87E−02 exon Mel. 48700791- 48700791- GGGCTCGGACAA CTCCAAGAACAA skip 48729643 48713208 TTTATGAAAACC TTTATGAAAACC GAAT (1083) GAAT (1084) 733 chr19: chr19: ACCGCCCTGCAC ACCGCCCTGCAC 7 15 1.00 2.95E−02 3′ss Mel. 617870- 617849- TGCTACAGGAGT TGCTACAGGAAG 618487 618487 CCTCCGCTCTGC GGCCTGACCTTC CACA (1085) GTCT (1086) 734 chr1: chr1: TCACAATTATAG GTGCTATTAAAG 7 15 1.00 1.48E−02 exon Mel. 220242774- 220242774- GGGAAGAGCTCG AAGAAGATCTCG skip 220247308 220246191 TGGTCTGGGTTG TGGTCTGGGTTG ATCC (1087) ATCC (1088) 735 chr1: chr1: CTCGTCTATGAT CTCGTCTATGAT 6 13 1.00 3.26E−02 3′ss Mel. 229431657- 229431657- ATCACCAGATGC ATCACCAGCCGA 229433266 229433228 CCGAATGCTAGC GAAACCTACAAT GAGC (1089) GCGC (1090) 736 chr11: chr11: CAATGCCACAGG CAATGCCACAGG 4 9 1.00 1.30E−02 3′ss Mel. 57193182- 57193143- GCAGGCTGGAAG GCAGGCTGACTG 57193461 57193461 GCTGGGATGCAT CAAAGCCCAGGA GGGA (1091) TGAG (1092) 737 chr11: chr11: TCAGAAGAGAAA TCAGAAGAGAAA 3 7 1.00 3.02E−02 3′ss Mel. 66105278- 66105360- ATCGGATGACAG ATCGGATGGACC 66105713 66105713 GCGGACCCACAG TTGACCCTGCTG GCCC (1093) TTCA (1094) 738 chr7: chr7: TGACTGCCGCTT CTAAAGCCTTCT 3 7 1.00 2.44E−02 exon Mel. 44251203- 44250723- TCTCTCAGGCCC ATAAAACTGCCC incl. 44251845 44251845 GGAAACAAAACT GGAAACAAAACT CATG (1095) CATG (1096) 739 chr12: chr12: ATGCAGATACAC ATGCAGATACAC 2 5 1.00 1.43E−02 exon Mel. 57925889- 57926098- AAAGCAAGCCAT AAAGCAAGGTGC skip 57926354 57926354 GCAGTTTGGTCA ACCAGCTATATG GCTC (1097) AAAC (1098) 740 chr4: chr4: TACTGATCATAT AAGAGTGCCAAA 2 5 1.00 2.55E−03 exon Mel. 48853992- 48859382- TGTCCAAGTCAA AAAAGAAGTCAA skip 48862741 48862741 AGTAAACAAGTA AGTAAACAAGTA TGGA (1099) TGGA (1100) 741 chr2: chr2: TGTCATCCATTG TGTCATCCATTG 1 3 1.00 2.77E−02 3′ss Mel. 27604588- 27604672- TGGAAGAGCCCC TGGAAGAGCTGC 27604992 27604992 GAAACACAGCAG TGGATCAGTGCC AGCT (1101) TGGC (1102) 742 chr6: chr6: TACCGGAAACCT GCTGCCAAAGCC 1 3 1.00 4.97E−02 5′ss Mel. 133136363- 133136227- AGGAAAAGGCGC TTAGACAAGCGC 133137599 133137599 CAAGCCCATCTT CAAGCCCATCTT TGTG (1103) TGTG (1104) 743 chr12: chr12: GGGTGCAAAAGA GGGTGCAAAAGA 0 1 1.00 8.93E−03 3′ss Mel. 57032980- 57033091- TCCTGCAGCCAT TCCTGCAGGACT 57033763 57033763 TCCAGGTTGCTG ACAAATCCCTCC AGGT (283) AGGA (284) 744 chr14: chr14: AGGATATCGGTT AGGATATCGGTT 0 1 1.00 1.46E−02 3′ss Mel. 50044571- 50050393- TCATTAAGAAAG TCATTAAGTTGG 50052667 50052667 ACCTGAGCTGTC ACTAAATGCTCT TTCC (1105) TCCT (1106) 745 chr16: chr16: GCGGCGGGCAGT GCGGCGGGCAGT 0 1 1.00 1.39E−02 3′ss Mel. 85833358- 85833358- GGCGGCAGGTGT GGCGGCAGAATG 85834789 85834810 ACATTTTTATCT TTGGCTACCAGG TTCA (1107) GTAT (1108) 746 chr19: chr19: TATCCAGCACTG CCTGATTCTCCC 0 1 1.00 3.56E−02 exon Mel. 35647877- 35646514- ACCACATGGACA CACCAGAGGACA incl. 35648323 35648323 GACGTTGAAAGA GACGTTGAAAGA TACC (1109) TACC (1110) 747 chr21: chr21: TTCATCATGGTG TTCATCATGGTG 0 1 1.00 1.84E−02 3′ss Mel. 27254101- 27254082- TGGTGGAGCTCT TGGTGGAGGTTG 27264033 27264033 CCTCTTGTTTTT ACGCCGCTGTCA CAGG (1111) CCCC (1112) 748 chr21: chr21: TGAAATCAGAAA TGAAATCAGAAA 0 1 1.00 3.04E−02 3′ss Mel. 46271557- 46271542- AAAATATGTTTA AAAATATGGCCT 46275124 46275124 TTTTGTTTCAGG GTTTAAAGAAGA CCTG (1113) AAAC (1114) 749 chr3: chr3: CAACGAGAACAA CAACGAGAACAA 0 1 1.00 4.76E−04 3′ss Mel. 101401353- 101401336- GCTATCAGTTAC GCTATCAGGGCT 101401614 101401614 TTTTACCCCACA GCTAAGGAAGCA GGGC (297) AAAA (298) 750 chr4: chr4: CCATGGTCAAAA CCATGGTCAAAA 0 1 1.00 4.92E−05 3′ss Mel. 152022314- 152022314- AATGGCAGCACC AATGGCAGACAA 152024139 152024022 AACAGGTCCGCC TGATTGAAGCTC AAAT (344) ACGT (345) 751 chr9: chr9: GCAAGGATATAT GCAAGGATATAT 0 1 1.00 4.68E−04 3′ss Mel. 86593213- 86593194- AATAACTGCTGC AATAACTGATTG 86593287 86593287 TTTATTTTTCCA GTGTGCCCGTTT CAGA (1115) AATA (1116) 752 chr4: chr4: GAACTGCAAAGG AGTGAATGTAGT 27 54 0.97 4.49E−02 exon Mel. 169911479- 169911479- CTTCAGAGGATT TGCACCAGGATT incl. 169919352 169923221 TGTACACACAGA TGTACACACAGA TATG (1117) TATG (1038) 753 chrX: chrX: TTGGAGATCAGG GATCTGGATTCT 21 42 0.97 2.52E−02 5′ss Mel. 102940188- 102940188- ACGCAAAGGTCA CGTTTCAGGTCA 102942916 102941558 CCATCAGAAAAG CCATCAGAAAAG CTAA (1118) CTAA (1119) 754 chr5: chr5: TGGAAGAGGCTA TGGAAGAGGCTA 13 26 0.95 2.18E−02 exon Mel. 137503767- 137504377- CCTCTGGGGTCA CCTCTGGGGTAA skip 137504910 137504910 ATGAGAGTGAAA CCCCCGGGACTT TGGC (1120) TGCC (1121) 755 chr13: chr13: TCTGGAGCCATA TCTGGAGCCATA 11 22 0.94 4.45E−02 exon Mel. 114291015- 114291015- CGTGACAGTGAC CGTGACAGAAAT skip 114294434 114292132 CTGACCAACGGT GGCTCAGGGAAC GCAG (1122) TGTT (1123) 756 chr16: chr16: CATCAAGCAGCT CATCAAGCAGCT 11 22 0.94 4.68E−04 3′ss Mel. 57473207- 57473246- GTTGCAATGTTT GTTGCAATCTGC 57474683 57474683 AGTCCCAGGAAG CCACAAAGAATC CACC (822) CAGC (823) 757 chr22: chr22: CTGCAGTATCTG CTGCAGTATCTG 28 52 0.87 1.79E−02 3′ss Mel. 31724845- 31724910- TAACCGAGGTCT TAACCGAGGTTT 31731677 31731677 CCAGGCACCAGG CTCCTCTGCCTC AGCC (1124) CTAC (1125) 758 chrX: chrX: ACTAATCTTCAG CAAACACCTCTT 14 26 0.85 1.55E−02 exon Mel. 123224814- 123224614- CATGCCATTCGG GATTATAATCGG incl. 123227867 123227867 CGTGGCACAAGC CGTGGCACAAGC CTAA (456) CTAA (457) 759 chr7: chr7: TGATTTCAAGTT TGATGAGACTCC 56 100 0.83 5.42E−03 exon Mel. 5028808- 5035213- TGAACAAGGGGT AGACAGAGGGGT skip 5036240 5036240 TGGCATCTGCAC TGGCATCTGCAC ATCC (1126) ATCC (1127) 760 chr8: chr8: AGCGAGCTCCTC CCGGGGATTGCC 29 52 0.82 4.95E−02 5’ss Mel. 146076780- 146076780- AGCCTCAGGCAT GGCGCCAGGCAT 146078756 146078377 CTGCATCTGGGA CTGCATCTGGGA CCGA (1128) CCGA (1129) 761 chr5: chr5: AGTTTCTACTAG AGTTTCTACTAG 7 13 0.81 3.69E−03 exon Mel. 139909381- 139909381- TCCAGTTGGTGA TCCAGTTGGGTT skip 139916922 139914946 CTCTCCTATTCC ACCATCCATTGA ATCT (1130) CCCA (1131) 762 chr1: chr1: CATAGTGGAAGT CATAGTGGAAGT 42 69 0.70 1.02E−05 3′ss Mel. 67890660- 67890642- GATAGATCTTCT GATAGATCTGGC 67890765 67890765 TTTTCACATTAC CTGAAGCACGAG AGTG (444) GACA (445) 763 chr22: chr22: GGAAAGGACAGC TGAGGTGCCCTA 40 65 0.69 3.49E−02 exon Mel. 42557364- 42557364- AAGCACAGGTGA AGCACAAGGTGA incl. 42564614 42565852 GACTGTGGAGAT GACTGTGGAGAT GAGA (1132) GAGA (1133) 764 chr6: chr6: AGTTGCATGTTG AGTTGCATGTTG 4 7 0.68 3.75E−03 exon Mel. 30587766- 30587766- ACTTTAGGGAGT ACTTTAGGAACG skip 30592659 30590608 CTGTGTGAAGCA TGAAGCTCTTGG GCAC (1134) AGCA (1135) 765 chr19: chr19: CCGCCCCCGTTC CCGCCCCCGTTC 41 65 0.65 1.89E−02 3′ss Mel. 2112966- 2112930- CATCCACGGGGG CATCCACGGACG 2113334 2113334 AGCTCAGTGTGA AGTGTGAGGACG ACAC (1136) CCAA (1137) 766 chr16: chr16: TGGAGCCGAACA TGGAGCCGAACA 8 13 0.64 4.20E−03 3′ss Mel. 89960266- 89960266- ACATCGTGCTCA ACATCGTGGTTC 89961490 89961445 GCGATGCCTGCC TGCTCCAGACGA GCTT (1138) GCCC (1139) 767 chr10: chr10: TGACGTTCTCTG TGACGTTCTCTG 47 73 0.62 1.42E−03 3′ss Mel. 75554088- 75554088- TGCTCCAGTGGT TGCTCCAGGTTC 75554298 75554313 TTCTCCCACAGG CCGGCCCCCAAG TTCC (466) TCGC (467) 768 chr12: chr12: GCCTGGAAAGCT GCCTGGAAAGCT 28 42 0.57 1.37E−03 3′ss Mel. 6675490- 6675502- ACCAAAAGGAGC ACCAAAAGGGAT 6675694 6675694 TGTCCAGACAGC CTCTGCAGGAGC TGGT (1140) TGTC (1141) 769 chr11: chr11: TGTTATTGTAGA TGTTATTGTAGA 37 55 0.56 4.34E−05 3′ss Mel. 85693031- 85693046- TTCTGGGGGTGG TTCTGGGGGCTT 85694908 85694908 ACTTCTCAAACC TGATGAACTAGG AACA (1142) TGGA (1143) 770 chr2: chr2: GGGGACCAAGAA GGGGACCAAGAA 59 86 0.54 2.26E−02 exon Mel. 55530288- 55529208- AAGCAGCATGGT AAGCAGCACCAT incl. 55535944 55535944 TGCACTGAAAAG GAATGACCTGGT ACTG (1144) GCAG (1145) 771 chr12: chr12: CAAAAAAGACCA CAAAAAAGACCA 13 19 0.51 2.94E−02 3′ss Mel. 7043741- 7043741- AAACTGAGGAAC AAACTGAGCAGG 7044712 7044709 TCCCTCGGCCAC AACTCCCTCGGC AGTC (1146) CACA (1147) 772 chr1: chr1: CCAAAGCAGAGA CCAAAGCAGAGA 9 13 0.49 3.58E−02 3′ss Mel 40209596- 40209596- CCCAGGAGGTGT CCCAGGAGGGAG 40211085 40211046 ACATGGACATCA AGCCCATTGCTA AGAT (1148) AAAA (1149) 773 chr4: chr4: ACTGGGCTTCCA ACTGGGCTTCCA 63 86 0.44 9.76E−04 exon Mel. 54266006- 54266006- CCGAGCAGAAAC CCGAGCAGGAGA incl. 54280781 54292038 AGCACTTCTTCT TTACCTGGGGCA CAGT (848) ATTG (849) 774 chr20: chr20: TGCCTAAGGCGG TGCCTAAGGCGG 61 83 0.44 3.34E−02 3′ss Mel. 30310151- 30310133- ATTTGAATCTCT ATTTGAATAATC 30310420 30310420 TTCTCTCCCTTC TTATCTTGGCTT AGAA (479) TGGA (480) 775 chr4: chr4: GCCGAATCACCT ACTGGGCTTCCA 63 84 0.41 3.70E−03 exon Mel. 54280889- 54266006- GATCTAAGGAGA CCGAGCAGGAGA incl. 54292038 54292038 TTACCTGGGGCA TTACCTGGGGCA ATTG (1150) ATTG (849) 776 chr1: chr1: ACGCCGCAAGTC AGCACCCATGGG 66 87 0.39 2.24E−02 exon Mel. 47024472- 47024472- CTCCAGAGGAAC TGCAGGGGGAAC incl. 47025905 47027149 AGCAGCACAATG AGCAGCACAATG GACC (1151) GACC (1152) 777 chr1: chr1: AACCAGTAACAA AACCAGTAACAA 59 76 0.36 1.42E−02 3′ss Mel. 150249040- 150249040- CGGAACCTCAGA CGGAACCTAGTC 150252050 150252053 GTCCAGATCTGA CAGATCTGAACG ACGA (1153) ATGC (1154) 778 chr20: chr20: GAGACCGCGTGC GAGACCGCGTGC 70 90 0.36 3.80E−03 3′ss Mel. 62577996- 62577993- GAGGACCGCAGC GAGGACCGCAAT 62587612 62587612 AATGCAGAGTCC GCAGAGTCCCTG CTGG (1155) GACA (1156) 779 chr1: chr1: GTCTCTGGCAAG GTCTCTGGCAAG 78 100 0.35 3.86E−02 3′ss Mel. 211836994- 211836970- TAATCCAGAACT TAATCCAGTAAT 211840447 211840447 TCTTAATCTTCC TAAGAAGAAAGT ATCC (1157) TCAT (1158) 780 chr3: chr3: AAGCATGTAGAA AAGCATGTAGAA 44 56 0.34 4.73E−02 3′ss Mel. 133305566- 133305566- AGCCGGAACAGG AGCCGGAAGGAT 133306002 133306739 TACTTAAAATGA AAAGAAATGGAG ATGC (1159) AAGA (1160) 781 chr1: chr1: AGCACCCATGGG AGCACCCATGGG 69 87 0.33 4.36E−02 exon Mel. 47025949- 47024472- TGCAGGGGCAAG TGCAGGGGGAAC incl. 47027149 47027149 CTCCAGAAAAGG AGCAGCACAATG GACT (1161) GACC (1152) 782 chr1: chr1: TCCACAAGAGCG AGGCGGTGAGTG 46 58 0.33 4.32E−02 5′ss Mel. 17330906- 17330906- AGGAGGCGAAGC TCGGACAGAAGC 17331201 17331186 GGGTGCTGCGGT GGGTGCTGCGGT ATTA (1162) ATTA (1163) 783 chr1: chr1: TCCGCCCCACAG GGCGGAGACATG 74 91 0.29 8.93E−03 5′ss Mel. 155917806- 155917806- TCCACGAGACTT GACCAGAGACTT 155920089 155920059 TACCAGAATGCA TACCAGAATGCA GGAC (1164) GGAC (1165) 784 chrl7: chrl7: TTGATCTTCGGC TTGATCTTCGGC 72 84 0.22 4.78E−02 3′ss Mel. 38080478- 38080473- CCCACACGAACA CCCACACGCAGA 38083736 38083736 GCAGAGAGGGGC GAGGGGCAGCAG AGCA (1166) GATG (1167) 785 chr2: chr2: GAAAAACTTTCC GAAAAACTTTCC 81 94 0.21 4.90E−02 3′ss Mel. 242590750- 242590750- AGCCATTGGGGG AGCCATTGGAGG 242592926 242592721 GACAGGCCCCAC TTGTCGGGACAT CTCG (1168) TTCA (1169) 786 chr9: chr9: GCGCTCGCCCGG CCGCAGGATACC 76 86 0.18 2.12E−02 5′ss Mel. 37422830- 37422802- GCGGCAGACTGT CGCCGAGGCTGT 37424841 37424841 GAGGTGGAGCAG GAGGTGGAGCAG TGGG (1170) TGGG (1171) 787 chr20: chr20: CGGGACGACTTC GCAGCATCTGCC 78 86 0.14 3.03E−02 exon Mel. 32661672- 32661441- TACGACAGGCTC ATATACAGGCTC incl. 32663679 32663679 TTCGACTACCGG TTCGACTACCGG GGCC (1172) GGCC (1173) 788 chr3: chr3: ACTGAAGCAGCA ACTGAAGCAGCA 92 98 0.09 3.80E−03 3′ss Mel. 184084588- 184084588- ACACGCCTCTCT ACACGCCTGCTG 184085964 184085900 GCGTACGTGTCC AGATTGAGAGCT TATG (1174) GCTG (1175) 789 chrl9: chrl9: CTGCCGGCGGAG CTGCCGGCGGAG 93 99 0.09 7.19E−03 3′ss Mel. 58817582- 58817582- AATATAAGGAGA AATATAAGGTGT 58823531 58823562 TGGACAAACCGT GTGTGACCATGG GTGG (1176) AACG (1177) 790 chr5: chr5: CAACCTCTAAGA CAACCTCTAAGA 97 99 0.03 2.75E−02 3′ss Mel. 179225591- 179225576- CTGGAGCGGTTC CTGGAGCGTGGG 179225927 179225927 TTCTTCCGCAGT AACATCGAGCAC GGGA (1178) CCGG (1179)

Certain splice variants are associated with more than one disease, and thus appear in Table 1 more than one time. In certain instances, splice variants associated with more than one cancer type may have different expression levels in each disease, so there may be more than one set of expression data for a given splice variant. Variants differentially expressed across all tested cancer types can be used to evaluate cells having SF3B1 neomorphic mutations in additional cancer types. Such variants are shown in the following rows of Table 1 (triplicates represent the same splice junction, measured in different cancer types): [13, 272, 525], [27, 286, 527], [33, 536, 330], [107, 445, 657], [28, 350, 573], [229, 762, 467], [240, 508, 767], [7, 356, 524], [76, 374, 596], [35, 547, 280], [84, 364, 571], [85, 564, 297], [24, 597, 296], [21, 372, 545], [36, 576, 407], [105, 423, 639], [62, 580, 447], [31, 279, 528], [235, 758, 439], [306, 89, 666], [34, 295, 533], [390, 72, 640], [48, 343, 554], [360, 65, 540], [178, 329, 750], [71, 265, 556], [15, 283, 530], [18, 267, 583], [129, 418, 622], [333, 25, 541], [247, 500, 774], [259, 5, 542], [152, 438, 615], [292, 1, 517], [81, 543, 443], [347, 70, 592], [91, 431, 617], [30, 298, 582], [17, 334, 602], [16, 276, 559], [51, 426, 548], [118, 401, 566], [83, 435, 574], and [269, 45, 546]. In certain embodiments, variants that are nonspecific to a particular cancer type can be chosen from the following rows of Table 1: [13, 272, 525], [27, 286, 527], [33, 536, 330], [107, 445, 657], [28, 350, 573], [240, 508, 767], [7, 356, 524], [84, 364, 571], [24, 597, 296], [21, 372, 545], [105, 423, 639], [62, 580, 447], [31, 279, 528], [235, 758, 439], [306, 89, 666], [34, 295, 533], [390, 72, 640], [360, 65, 540], [178, 329, 750], [71, 265, 556], [15, 283, 530], [18, 267, 583], [247, 500, 774], [152, 438, 615], [292, 1, 517], [81, 543, 443], [91, 431, 617], [30, 298, 582], [16, 276, 559], or [51, 426, 548].

Certain embodiments of the invention provide splice variants as markers for cancer. In certain circumstances, cancer cells with a neomorphic SF3B1 protein demonstrate differential expression of certain splice variants compared to cells without a neomorphic SF3B1 protein. The differential expression of one or more splice variants therefore may be used to determine whether a patient has cancer with a neomorphic SF3B1 mutation. In certain embodiments, the patient is also determined to have a cancer cell having a mutant SF3B1 protein. In these methods, one or more of the splice variants listed in Table 1 can be measured to determine whether a patient has cancer with a neomorphic SF3B1 mutation. In certain embodiments, one or more aberrant splice variants from Table 1 are measured. In other embodiments, one or more canonical splice variants are measured. Sometimes, both aberrant and canonical variants are measured.

In some embodiments, one or more aberrant splice variants selected from rows 260, 262, 263, 265, 266, 267, 272, 273, 275, 276, 277, 279, 281, 282, 286, 287, 288, 290, 294, 295, 296, 298, 299, 301, 302, 304, 305, 306, 308, 310, 312, 313, 315, 316, 318, 320, 321, 322, 323, 324, 325, 326, 327, 328, 329, 330, 331, 335, 337, 339, 342, 346, 348, 349, 350, 352, 353, 354, 355, 356, 357, 358, 362, 363, 365, 366, 368, 369, 370, 372, 375, 377, 378, 379, 380, 381, 382, 383, 384, 387, 388, 389, 390, 391, 392, 393, 394, 397, 398, 400, 402, 403, 404, 405, 406, 413, 415, 416, 417, 419, 420, 421, 424, 425, 428, 429, 430, 431, 432, 433, 436, 437, 438, 439, 440, 441, 442, 443, 444, 445, 446, 447, 448, 449, 450, 451, 452, 454, 455, 456, 458, 459, 460, 461, 462, 464, 465, 468, 469, 471, 472, 473, 474, 475, 476, 477, 478, 480, 481, 483, 484, 485, 486, 487, 488, 490, 491, 494, 496, 497, 498, 500, 501, 502, 503, 504, 505, 506, 507, 508, 509, 510, 511, 513, 514, 515, or 516 of Table 1 can be measured in a patient suspected of having CLL. In additional embodiments, a patient suspected of having CLL can be identified by measuring the amounts of one or more of the following aberrant splice variants listed in Table 1: row 259, 269, 270, 271, 274, 278, 280, 282, 292, 296, 297, 302, 306, 330, 331, 333, 343, 347, 355, 360, 361, 371, 373, 376, 378, 390, 391, 407, 408, 423, 424, 425, 433, 434, 439, 443, 447, 448, 451, 452, 453, 458, 459, 460, 462, 463, 466, 467, 468, 469, 470, 472, 479, 482, or 489. In additional embodiments, a patient suspected of having CLL can be identified by measuring the amounts of one or more of the following aberrant splice variants listed in Table 1: row 282, 292, 296, 302, 306, 330, 331, 343, 355, 360, 373, 378, 390, 391, 423, 424, 425, 433, 434, 439, 443, 447, 448, 451, 452, 458, 459, 460, 462, 463, 466, 468, 469, 470, 472, 479, 482, or 489. In still further embodiments, a patient suspected of having CLL can be identified by measuring the amount of one or more of the following aberrant splice variants listed in Table 1: row 282, 296, 302, 306, 330, 331, 355, 378, 390, 391, 424, 425, 433, 439, 443, 447, 448, 451, 452, 458, 459, 460, 462, 468, 469, or 472.

In other embodiments, one or more aberrant splice variants selected from rows 2, 3, 4, 7, 9, 10, 11, 13, 16, 18, 19, 20, 21, 22, 23, 24, 27, 28, 30, 31, 32, 33, 34, 37, 38, 39, 40, 41, 42, 43, 46, 47, 49, 50, 52, 53, 54, 56, 57, 58, 61, 62, 63, 64, 66, 67, 68, 71, 72, 75, 77, 78, 79, 80, 81, 82, 84, 87, 88, 89, 90, 91, 92, 94, 95, 97, 98, 99, 100, 101, 103, 104, 106, 107, 108, 109, 110, 111, 112, 113, 114, 116, 117, 119, 120, 121, 122, 123, 124, 125, 126, 127, 131, 132, 133, 134, 135, 136, 138, 139, 140, 141, 142, 143, 144, 146, 147, 150, 152, 154, 155, 156, 157, 159, 163, 164, 165, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 185, 186, 187, 188, 189, 190, 191, 192, 193, 194, 195, 196, 197, 198, 199, 200, 201, 202, 203, 204, 205, 206, 207, 208, 209, 210, 211, 212, 213, 214, 215, 216, 217, 218, 219, 220, 221, 222, 223, 224, 225, 226, 227, 228, 230, 231, 232, 233, 235, 236, 237, 238, 239, 240, 241, 242, 243, 244, 247, 249, 250, 251, 252, 253, 254, 255, 256, or 257 of Table 1 can be measured in a patient suspected of having breast cancer. In additional embodiments, a patient suspected of having breast cancer can be identified by measuring the amounts of one or more of the following aberrant splice variants listed in Table 1: row 7, 8, 9, 10, 26, 48, 66, 105, 121, 135, 136, or 166. In additional embodiments, a patient suspected of having breast cancer can be identified by measuring the amounts of one or more of the following aberrant splice variants listed in Table 1: row 7, 8, 9, 10, 26, 48, 66, 105, 121, 135, or 136. In still further embodiments, a patient suspected of having breast cancer can be identified by measuring the amount of one or more of the following aberrant splice variants listed in Table 1: row 7, 9, 10, 66, 121, 135, or 136.

In further embodiments, one or more aberrant splice variants selected from rows 518, 519, 520, 521, 523, 524, 525, 526, 527, 528, 529, 531, 533, 534, 536, 537, 538, 539, 543, 544, 545, 549, 551, 552, 553, 555, 556, 557, 558, 559, 560, 561, 562, 563, 565, 567, 568, 569, 570, 572, 573, 575, 577, 578, 579, 580, 581, 582, 583, 584, 585, 588, 589, 590, 591, 593, 595, 597, 598, 599, 600, 601, 603, 604, 605, 606, 607, 608, 609, 610, 611, 612, 613, 614, 615, 616, 617, 618, 619, 620, 621, 623, 625, 627, 628, 629, 630, 632, 634, 635, 636, 637, 638, 640, 641, 643, 644, 645, 646, 647, 648, 649, 650, 651, 652, 654, 657, 658, 659, 661, 662, 663, 664, 665, 666, 667, 668, 669, 670, 671, 672, 673, 674, 675, 676, 677, 678, 680, 682, 683, 684, 685, 686, 687, 688, 689, 690, 692, 694, 696, 697, 698, 699, 700, 701, 702, 703, 705, 706, 707, 708, 709, 710, 711, 712, 713, 714, 715, 716, 717, 718, 719, 720, 721, 722, 723, 724, 725, 726, 727, 728, 730, 731, 732, 733, 734, 735, 736, 737, 738, 739, 740, 741, 742, 743, 744, 745, 746, 747, 748, 750, 751, 752, 753, 754, 755, 756, 757, 758, 759, 760, 763, 764, 765, 766, 767, 768, 770, 771, 772, 773, 774, 775, 776, 777, 778, 779, 780, 781, 782, 783, 784, 785, 786, 787, 788, 789, or 790 of Table 1 can be measured in a patient suspected of having melanoma. In additional embodiments, a patient suspected of having melanoma can be identified by measuring the amounts of one or more of the following aberrant splice variants listed in Table 1: row 519, 521, 522, 535, 554, 587, 594, 601, 618, 639, 654, 655, 670, 679, 680, 727, 729, or 730. In additional embodiments, a patient suspected of having melanoma can be identified by measuring the amounts of one or more of the following aberrant splice variants listed in Table 1: row 519, 521, 522, 535, 554, 587, 601, 618, 639, 654, 670, 680, 727, or 730. In still further embodiments, a patient suspected of having melanoma can be identified by measuring the amount of one or more of the following aberrant splice variants listed in Table 1: row 519, 521, 601, 618, 654, 670, 680, 727, or 730.

In some embodiments, one or more of the aberrant variants are selected from rows 21, 31, 51, 81, 118, 279, 372, 401, 426, 443, 528, 543, 545, 548 or 566 of Table 1. In certain embodiments, a patient suspected of having cancer can be identified by measuring the amount of one or more of the aberrant variants selected from 21, 31, 51, 81, 118, 279, 372, 401, 426, 443, 528, 543, 545, 548 or 566. In various embodiments the cancer may be CLL, breast cancer, or melanoma, for example.

Additional methods include predicting or monitoring the efficacy of a treatment for cancer by measuring the level of one or more aberrant splice variants in samples obtained from patients before or during the treatment. For example, a decrease in the levels of one or more aberrant splice variants over the course of treatment may indicate that the treatment is effective. In other cases, the absence of a decrease or an increase in the levels of one or more aberrant splice variants over the course of treatment may indicate that the treatment is not effective and should be adjusted, supplemented, or terminated. In some embodiments, the splice variants are used to track and adjust individual patient treatment effectiveness.

Embodiments of the invention also encompass methods of stratifying cancer patients into different categories based on the presence or absence of one or more particular splice variants in patient samples or the detection of one or more particular splice variants at levels that are elevated or reduced relative to those in normal cell samples. Categories may be different prognostic categories, categories of patients with varying rates of recurrence, categories of patients that respond to treatment and those that do not, and categories of patients that may have particular negative side effects, and the like. According to the categories in which individual patients fall, optimal treatments may then be selected for those patients, or particular patients may be selected for clinical trials.

Embodiments also encompass methods of distinguishing cancerous cells with SF3B1 neomorphic mutations from normal cells by using the splice variants disclosed herein as markers. Such methods may be employed, for example, to assess the growth or loss of cancerous cells and to identify cancerous cells to be treated or removed. In some embodiments, the splice variants are measured in cancerous tissue having cells with a neomorphic SF3B1 mutation before and after anti-cancer treatment, for the purpose of monitoring the effect of the treatment on cancer progression.

In additional embodiments, administering an SF3B1 modulator to a cell, such as a cancer cell, can alter the differential expression of splice variants. Accordingly, the change in expression of one or more splice variants can be used to evaluate the effect of the SF3B1 modulator on the SF3B1 protein. In one embodiment, the effect of an SF3B1 modulator on a CLL cell is evaluated by applying an SF3B1 modulator to such a cell, then detecting or quantifying one or more of the splice variants in Table 1. In additional embodiments the one or more splice variants are chosen from rows 258-516 of Table 1. In further embodiments, the one or more splice variants are chosen from rows 260, 262, 263, 265, 266, 267, 272, 273, 275, 276, 277, 279, 281, 282, 286, 287, 288, 290, 294, 295, 296, 298, 299, 301, 302, 304, 305, 306, 308, 310, 312, 313, 315, 316, 318, 320, 321, 322, 323, 324, 325, 326, 327, 328, 329, 330, 331, 335, 337, 339, 342, 346, 348, 349, 350, 352, 353, 354, 355, 356, 357, 358, 362, 363, 365, 366, 368, 369, 370, 372, 375, 377, 378, 379, 380, 381, 382, 383, 384, 387, 388, 389, 390, 391, 392, 393, 394, 397, 398, 400, 402, 403, 404, 405, 406, 413, 415, 416, 417, 419, 420, 421, 424, 425, 428, 429, 430, 431, 432, 433, 436, 437, 438, 439, 440, 441, 442, 443, 444, 445, 446, 447, 448, 449, 450, 451, 452, 454, 455, 456, 458, 459, 460, 461, 462, 464, 465, 468, 469, 471, 472, 473, 474, 475, 476, 477, 478, 480, 481, 483, 484, 485, 486, 487, 488, 490, 491, 494, 496, 497, 498, 500, 501, 502, 503, 504, 505, 506, 507, 508, 509, 510, 511, 513, 514, 515, or 516 of Table 1. In further embodiments, the one or more splice variants are chosen from rows 259, 269, 270, 271, 274, 278, 280, 282, 292, 296, 297, 302, 306, 330, 331, 333, 343, 347, 355, 360, 361, 371, 373, 376, 378, 390, 391, 407, 408, 423, 424, 425, 433, 434, 439, 443, 447, 448, 451, 452, 453, 458, 459, 460, 462, 463, 466, 467, 468, 469, 470, 472, 479, 482, or 489. In additional embodiments, the one or more splice variants are chosen from rows 282, 292, 296, 302, 306, 330, 331, 343, 355, 360, 373, 378, 390, 391, 423, 424, 425, 433, 434, 439, 443, 447, 448, 451, 452, 458, 459, 460, 462, 463, 466, 468, 469, 470, 472, 479, 482, or 489 of Table 1. In still further embodiments, the one or more splice variants are chosen from rows 282, 296, 302, 306, 330, 331, 355, 378, 390, 391, 424, 425, 433, 439, 443, 447, 448, 451, 452, 458, 459, 460, 462, 468, 469, or 472 of Table 1.

In certain embodiments, the effect of an SF3B1 modulator on a breast cancer cell is evaluated by applying an SF3B1 modulator to such a cell, then detecting or quantifying one or more of the splice variants in Table 1. In additional embodiments the one or more splice variants are chosen from rows 1-257 of Table 1. In further embodiments, the one or more splice variants are chosen from rows 2, 3, 4, 7, 9, 10, 11, 13, 16, 18, 19, 20, 21, 22, 23, 24, 27, 28, 30, 31, 32, 33, 34, 37, 38, 39, 40, 41, 42, 43, 46, 47, 49, 50, 52, 53, 54, 56, 57, 58, 61, 62, 63, 64, 66, 67, 68, 71, 72, 75, 77, 78, 79, 80, 81, 82, 84, 87, 88, 89, 90, 91, 92, 94, 95, 97, 98, 99, 100, 101, 103, 104, 106, 107, 108, 109, 110, 111, 112, 113, 114, 116, 117, 119, 120, 121, 122, 123, 124, 125, 126, 127, 131, 132, 133, 134, 135, 136, 138, 139, 140, 141, 142, 143, 144, 146, 147, 150, 152, 154, 155, 156, 157, 159, 163, 164, 165, 167, 168, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 185, 186, 187, 188, 189, 190, 191, 192, 193, 194, 195, 196, 197, 198, 199, 200, 201, 202, 203, 204, 205, 206, 207, 208, 209, 210, 211, 212, 213, 214, 215, 216, 217, 218, 219, 220, 221, 222, 223, 224, 225, 226, 227, 228, 230, 231, 232, 233, 235, 236, 237, 238, 239, 240, 241, 242, 243, 244, 247, 249, 250, 251, 252, 253, 254, 255, 256, or 257 of Table 1. In additional embodiments, the one or more splice variants are chosen from rows 7, 8, 9, 10, 26, 48, 66, 105, 121, 135, 136, or 166 of Table 1. In further embodiments, the one or more splice variants are chosen from rows 7, 8, 9, 10, 26, 48, 66, 105, 121, 135, or 136 of Table 1. In still further embodiments, the one or more splice variants are chosen from rows 7, 9, 10, 66, 121, 135, or 136 of Table 1.

In a further embodiment, the effect of an SF3B1 modulator on a melanoma cell is evaluated by applying an SF3B1 modulator to such a cell, then detecting or quantifying one or more of the splice variants in Table 1. In additional embodiments the one or more splice variants are chosen from rows 517-790 of Table 1. In further embodiments, the one or more splice variants are chosen from rows 518, 519, 520, 521, 523, 524, 525, 526, 527, 528, 529, 531, 533, 534, 536, 537, 538, 539, 543, 544, 545, 549, 551, 552, 553, 555, 556, 557, 558, 559, 560, 561, 562, 563, 565, 567, 568, 569, 570, 572, 573, 575, 577, 578, 579, 580, 581, 582, 583, 584, 585, 588, 589, 590, 591, 593, 595, 597, 598, 599, 600, 601, 603, 604, 605, 606, 607, 608, 609, 610, 611, 612, 613, 614, 615, 616, 617, 618, 619, 620, 621, 623, 625, 627, 628, 629, 630, 632, 634, 635, 636, 637, 638, 640, 641, 643, 644, 645, 646, 647, 648, 649, 650, 651, 652, 654, 657, 658, 659, 661, 662, 663, 664, 665, 666, 667, 668, 669, 670, 671, 672, 673, 674, 675, 676, 677, 678, 680, 682, 683, 684, 685, 686, 687, 688, 689, 690, 692, 694, 696, 697, 698, 699, 700, 701, 702, 703, 705, 706, 707, 708, 709, 710, 711, 712, 713, 714, 715, 716, 717, 718, 719, 720, 721, 722, 723, 724, 725, 726, 727, 728, 730, 731, 732, 733, 734, 735, 736, 737, 738, 739, 740, 741, 742, 743, 744, 745, 746, 747, 748, 750, 751, 752, 753, 754, 755, 756, 757, 758, 759, 760, 763, 764, 765, 766, 767, 768, 770, 771, 772, 773, 774, 775, 776, 777, 778, 779, 780, 781, 782, 783, 784, 785, 786, 787, 788, 789, or 790 of Table 1. In still further embodiments, the one or more splice variants are chosen from rows 519, 521, 522, 535, 554, 587, 594, 601, 618, 639, 654, 655, 670, 679, 680, 727, 729, or 730 of Table 1. In additional embodiments, the one or more splice variants are chosen from rows 519, 521, 522, 535, 554, 587, 601, 618, 639, 654, 670, 680, 727, or 730 of Table 1. In still further embodiments, the one or more splice variants are chosen from rows 519, 521, 601, 618, 654, 670, 680, 727, or 730 of Table 1.

In some embodiments, the effect of an SF3B1 modulator on a cancer cell is evaluated by applying an SF3B1 modulator to such a cell, then detecting or quantifying one or more of the aberrant variants selected from rows 21, 31, 51, 81, 118, 279, 372, 401, 426, 443, 528, 543, 545, 548 or 566 of Table 1. In various embodiments, the cancer cell may be a CLL cell, a breast cancer cell, or a melanoma cell, for example.

The specific splice variants that are useful for demonstrating the effect of an SF3B1 modulator on one type of cancer cell may not be useful for demonstrating an effect of the modulator on another type of cancer cell. Aberrant splice variants that are appropriate for revealing such effects in particular cancer cells will be apparent from the description and examples provided herein.

In some embodiments, aberrant splice variants that are present at elevated levels in a cell having a neomorphic SF3B1 protein are used as markers. In other embodiments, splice variants that have reduced levels in a cell having a neomorphic SF3B1 protein are used as markers. In some embodiments, more than one splice variant will be measured. When more than one splice variant is used, they may all have elevated levels, all have reduced levels, or a mixture of splice variants with elevated and reduced levels may be used. In certain embodiments of the methods described herein, more than one aberrant splice variant is measured. In other embodiments, at least one aberrant and at least one canonical splice variant is measured. In some cases, both an aberrant and canonical splice variant associated with a particular genomic location will be measured. In other circumstances, a measured canonical splice variant will be at a different genomic location from the measured aberrant splice variant(s).

Before performing an assay for splice variants in a cell, one may determine whether the cell has a mutant SF3B1 protein. In certain embodiments, the assay for splice variants is performed if the cell has been determined to have a neomorphic SF3B1 mutant protein.

Samples

Cell samples can be obtained from a variety of biological sources. Exemplary cell samples include but are not limited to a cell culture, a cell line, a tissue, oral tissue, gastrointestinal tissue, an organ, an organelle, a biological fluid, a blood sample, a urine sample, a skin sample, and the like. Blood samples may be whole blood, partially purified blood, or a fraction of whole or partially purified blood, such as peripheral blood mononucleated cells (PBMCs). The source of a cell sample may be a solid tissue sample such as a tissue biopsy. Tissue biopsy samples may be biopsies from breast tissue, skin, lung, or lymph nodes. Samples may be samples of bone marrow, including bone marrow aspirates and bone marrow biopsies.

In certain embodiments, the cells are human cells. Cells may be cancer cells, for example hematological cancer cells or solid tumor cells. Hematological cancers include chronic lymphocytic leukemia, acute lymphoblastic leukemia, acute myeloid leukemia, chronic myeloid leukemia, chronic myelomonocytic leukemia, acute monocytic leukemia, Hodgkin's lymphoma, Non-Hodgkin's lymphoma, and multiple myeloma. Solid tumors include carcinomas, such as adenocarcinomas, and may be selected from breast, lung, liver, prostate, pancreatic, colon, colorectal, skin, ovarian, uterine, cervical, or renal cancers. Cell samples may be obtained directly from a patient or derived from cells obtained from a patient, such as cultured cells derived from a biological fluid or tissue sample. Samples may be archived samples, such as kryopreserved samples, of cells obtained directly from a subject or of cells derived from cells obtained from a patient.

In certain embodiments, cells are obtained from patients suspected of having cancer. The patients may show signs and symptoms of cancer, such as one or more common symptoms of CLL, which include enlarged lymph nodes, liver, or spleen, higher-than-normal white blood cell counts, recurring infections, loss of appetite or early satiety, abnormal bruising, fatigue, and night sweats. In additional embodiments, the cells have a mutant SF3B1 protein.

Cell samples described herein may be used in any of the methods presently disclosed.

Detection of Splice Variants

Certain embodiments of the methods described herein involve detection or quantification of splice variants. A variety of methods exists for detecting and quantifying nucleic acids, and each may be adapted for detection of splice variants in the described embodiments. Exemplary methods include an assay to quantify nucleic acid such as nucleic acid barcoding, nanoparticle probes, in situ hybridization, microarray, nucleic acid sequencing, and PCR-based methods, including real-time PCR (RT-PCR).

Nucleic acid assays utilizing barcoding technology such as NanoString® assays (NanoString Technologies) may be performed, for example, as described in U.S. Pat. Nos. 8,519,115; 7,919,237; and in Kulkarni, M. M., 2011, “Digital Multiplexed Gene Expression Analysis Using the NanoString nCounter System.” Current Protocols in Molecular Biology, 94:25B.10.1-25B.10.17. In an exemplary assay, a pair of probes is used to detect a particular nucleotide sequence of interest, such as a particular splice variant of interest. The probe pair consists of a capture probe and a reporter probe and that each include a sequence of from about 35 to 50 bases in length that is specific for a target sequence. The capture probe includes an affinity label such as biotin at its 3′ end that provides a molecular handle for surface-attachment of target mRNAs for digital detection, and the reporter probe includes a unique color code at its 5′ end that provides molecular barcoding of the hybridized mRNA target sequence. Capture and reporter probe pairs are hybridized to target mRNA in solution, and after excess probes are removed, the target mRNA-probe complexes are immobilized in an nCounter® cartridge. A digital analyzer acquires direct images of the surface of the cartridge to detect color codes corresponding to specific mRNA splice variant sequences. The number of times a color-coded barcode for a particular splice variant is detected reflects the levels of a particular splice variant in the mRNA library. For the detection of splice variants, either the capture or the reporter probe may span a given splice variant's exon-exon or intron-exon junction. In other embodiments, one or both of the capture and reporter probes' target sequences correspond to the terminal sequences of two exons at an exon-exon junction or to the terminal sequences of an intron and an exon at an intron-exon junction, whereby one probe extends to the exon-exon or intron-exon junction, but does not span the junction, and the other probe binds a sequence that begins on opposite side of the junction and extends into the respective exon or intron.

In exemplary PCR-based methods, a particular splice variant may be detected by specifically amplifying a sequence that contains the splice variant. For example, the method may employ a first primer specifically designed to hybridize to a first portion of the splice variant, where the splice variant is a sequence that spans an exon-exon or intron-exon junction at which alternative splicing occurs. The method may further employ a second opposing primer that hybridizes to a segment of the PCR extension product of the first primer that corresponds to another sequence in the gene, such as a sequence at an upstream or downstream location. The PCR detection method may be quantitative (or real-time) PCR. In some embodiments of quantitative PCR, an amplified PCR product is detected using a nucleic acid probe, wherein the probe may contain one or more detectable labels. In certain quantitative PCR methods, the amount of a splice variant of interest is determined by detecting and comparing levels of the splice variant to an appropriate internal control.

Exemplary methods for detecting splice variants using an in situ hybridization assay such as RNAscope® (Advanced Cell Diagnostics) include those described by Wang, F., et al., “RNAscope: a novel in situ RNA analysis platform for formalin-fixed, paraffin-embedded tissues,” J. Mol. Diagn. 2012 January; 14(1):22-9. RNAscope® assays may be used to detect splice variants by designing a pair of probes that targets a given splice variant, and are hybridized to target RNA in fixed and permeabilized cells. Target probes are designed to hybridize as pairs which, when hybridized to the target sequence, create a binding site for a preamplifier nucleic acid. The preamplifier nucleic acid, in turn, harbors multiple binding sites for amplifier nucleic acids, which in turn contain multiple binding sites for a labeled probe carrying a chromogenic or fluorescent molecule. In some embodiments, one of the RNAscope® target probes spans a given splice variant's exon-exon or intron-exon junction. In other embodiments, the target probes' target sequences correspond to the terminal sequences of two exons at an exon-exon junction or to the terminal sequences of an intron and an exon at an intron-exon junction, whereby one probe in the target probe pair extends to the exon-exon or intron-exon junction, but does not span the junction, and the other probe binds a sequence beginning on opposite side of the junction and extending into the respective exon or intron.

Exemplary methods for detecting splice variants using nanoparticle probes such as SmartFlare™ (Millipore) include those described in Seferos et al., “Nano-flares: Probes for Transfection and mRNA Detection in Living Cells,” J. Am. Chem. Soc. 129(50):15477-15479 (2007) and Prigodich, A. E., et al., “Multiplexed Nanoflares: mRNA Detection in Live Cells,” Anal. Chem. 84(4):2062-2066 (2012). SmartFlare™ detection probes may be used to detect splice variants by generating gold nanoparticles that are modified with one or more nucleic acids that include nucleotide recognition sequences that (1) are each complementary to a particular splice variant to be detected and (2) are each hybridized to a complementary fluorophore-labeled reporter nucleic acid. Upon uptake of the probe by a cell, a target splice variant sequence may hybridize to the one or more nucleotide recognition sequences and displace the fluorophore-labeled reporter nucleic acid. The fluorophore-labeled reporter nucleic acid, whose fluorophore had been quenched due to proximity to the gold nanoparticle surface, is then liberated from the gold nanoparticle, and the fluorophore may then be detected when free of the quenching effect of the nanoparticle. In some embodiments, nucleotide recognition sequences in the probes recognize a sequence that spans a given splice variant's exon-exon or intron-exon junction. In some embodiments, nucleotide recognition sequences in the probes recognize a sequence that is only on one side of the splice variant's exon-exon or intron-exon junction, including a sequence that terminates at the junction and a sequence that terminates one or more nucleotides away from the junction.

Exemplary methods for detecting splice variants using nucleic acid sequencing include RNA sequencing (RNA-Seq) described in Ren, S. et al. “RNA-Seq analysis of prostate cancer in the Chinese population identifies recurrent gene fusions, cancer-associated long noncoding RNAs and aberrant alternative splicings.” Cell Res 22, 806-821, doi:10.1038/cr.2012.30 (2012); and van Dijk et al., “Ten years of next-generation sequencing technology.” Trends Genet 30(9):418-26 (2014). In some embodiments, high-throughput sequencing, such as next-generation sequencing (NGS) technologies, may be used to detected splice variants. For example, the method may employ commercial sequencing platforms available for RNA-Seq, such as, e.g., Illumina, SOLID, Ion Torrent, and Roche 454. In some embodiments, the sequencing method may include pyrosequencing. For example, a sample may be mixed with sequencing enzymes and primer and exposed to a flow of one unlabeled nucleotide at a time, allowing synthesis of the complementary DNA strand. When a nucleotide is incorporated, pyrophosphate is released leading to light emission, which is monitored in real time. In some embodiments, the sequencing method may include semiconductor sequencing. For example, proton instead of pyrophosphate may be released during nucleotide incorporation and detected in real time by ion sensors. In some embodiments, the method may include sequencing with reversible terminators. For example, the synthesis reagents may include primers, DNA polymerase, and four differently labelled, reversible terminator nucleotides. After incorporation of a nucleotide, which is identified by its color, the 3′ terminator on the base and the fluorophore are removed, and the cycle is repeated. In some embodiments, the method may include sequencing by ligation. For example, a sequencing primer may be hybridized to an adapter, with the 5′ end of the primer available for ligation to an oligonucleotide hybridizing to the adjacent sequence. A mixture of octamers, in which bases 4 and 5 are encoded by one of four color labels, may compete for ligation to the primer. After color detection, the ligated octamer may be cleaved between position 5 and 6 to remove the label, and the cycle may be repeated. Thereby, in the first round, the process may determine possible identities of bases in positions 4, 5, 9, 10, 14, 15, etc. The process may be repeated, offset by one base using a shorter sequencing primer, to determine positions 3, 4, 8, 9, 13, 14, etc., until the first base in the sequencing primer is reached.

Other nucleic acid detection and analytical methods that also distinguish between splice variants of a given exon-exon or intron-exon junction in a gene by identifying the nucleotide sequence on both sides of the junction may be utilized to detect or quantify the splice variants disclosed herein. For example, splice variants of an exon-exon junction may be detected by primer extension methods in which a primer that binds to one exon is extended into the exon on the other side of the junction according to the sequence of that adjacent exon. See, for example, McCullough, R. M., et al., “High-throughput alternative splicing quantification by primer extension and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry,” Nucleic Acids Research, 2005 Jun. 20; 33(11):e99; and Milani, L., et al., “Detection of alternatively spliced transcripts in leukemia cell lines by minisequencing on microarrays,” Clin. Chem. 52: 202-211 (2006). Detection of variants on a large scale may be performed using expression microarrays that carry exon-exon or intron-exon junction probes, as described, for example, in Johnson, J. M. et al., “Genome-wide survey of human alternative pre-mRNA splicing with exon junction microarrays,” Science 302: 2141-2144 (2003); and Modrek, B., et al., “Genome-wide detection of alternative splicing in expressed sequences of human genes,” Nucleic Acids Res 29: 2850-2859 (2001).

Various embodiments include reagents for detecting splice variants of the invention. In one example, reagents include NanoString® probes designed to measure the amount of one or more of the aberrant splice variants listed in Table 1. Probes for nucleic acid quantification assays such as barcoding (e.g. NanoString®), nanoparticle probes (e.g. SmartFlare™), in situ hybridization (e.g. RNAscope®), microarray, nucleic acid sequencing, and PCR-based assays may be designed as set forth above.

In these exemplary methods or in other methods for nucleic acid detection, aberrant splice variants may be identified using probes, primers, or other reagents which specifically recognize the nucleic acid sequence that is present in the aberrant splice variant but absent in the canonical splice variant. In other embodiments, the aberrant splice variant is identified by detecting the sequence that is specific to the aberrant splice variant in the context of the junction in which it occurs, i.e., the unique sequence is flanked by the sequences which are present on either side of the splice junction in the canonical splice variant. In such cases, the portion of the probe, primer, or other detection reagent that specifically recognizes its target sequence may have a length that corresponds to the length of the aberrant sequence or to or a portion of the aberrant sequence. In other embodiments, the portion of the probe, primer, or other detection reagent that specifically recognizes its target sequence may have a length that corresponds to the length of the aberrant sequence plus the length of a chosen number of nucleotides from one or both of the sequences which flank the aberrant sequence at the splice junction. Generally, the probe or primer should be designed with a sufficient length to reduce non-specific binding. Probes, primers, and other reagents that detect aberrant or canonical splice variants may be designed according to the technical features and formats of a variety of methods for detection of nucleic acids.

SF3B1 Modulators

A variety of SF3B1 modulating compounds are known in the art, and can be used in accordance with the methods described herein. In some embodiments, the SF3B1 modulating compound is a pladienolide or pladienolide analog. A “pladienolid analog” refers to a compound which is structurally related to a member of the family of natural products known as the pladienolides. Plandienolides were first identified in the bacteria Streptomyces platensis (Sakai, Takashi; Sameshima, Tomohiro; Matsufuji, Motoko; Kawamura, Naoto; Dobashi, Kazuyuki; Mizui, Yoshiharu. “Pladienolides, New Substances from Culture of Streptomyces platensis Mer-11107. I. Taxonomy, Fermentation, Isolation and Screening.” The Journal of Antibiotics. 2004, Vol. 57, No. 3). One of these compounds, pladienolide B, targets the SF3B spliceosome to inhibit splicing and alter the pattern of gene expression (Kotake et al., “Splicing factor SF3b as a target of the antitumor natural product pladienolide”, Nature Chemical Biology 3:570-575 [2007]). Certain pladienolide B analogs are described in WO 2002/060890; WO 2004/011459; WO 2004/011661; WO 2004/050890; WO 2005/052152; WO 2006/009276; and WO 2008/126918.

U.S. Pat. Nos. 7,884,128 and 7,816,401, both entitled “Process for Total Synthesis of Pladienolide B and Pladienolide D,” describe methods for synthesizing pladienolide B and D. Synthesis of pladienolide B and D may also be performed using methods described in Kanada et al., “Total Synthesis of the Potent Antitumor Macrolides Pladienolide B and D,” Angew. Chem. Int. Ed. 46:4350-4355 (2007). Kanada et al., U.S. Pat. No. 7,550,503, and International Publication No. WO 2003/099813 (WO '813), entitled “Novel Physiologically Active Substances,” describe methods for synthesizing E7107 (Compound 45 of WO '813) from pladienolide D (11107D of WO '813). In some embodiments, the SF3B1 modulator is pladienolide B. In other embodiments, the SF3B1 modulator is pladienolide D. In further embodiments, the SF3B1 modulator is E7107.

In some embodiments, the SF3B1 modulator is a compound described in U.S. application Ser. No. 14/710,687, filed May 13, 2015, which is incorporated herein by reference in its entirety. In some embodiments, the SF3B1 modulating compound is a compound having one of formulas 1-4 as set forth in Table 2. Table 2. Exemplary SF3B1 modulating compounds.

Compound Structure

1

2

3

4

The methods described herein may be used to evaluate known and novel SF3B1 modulating compounds.

Methods of Treatment

Various embodiments of the invention include treating a patient diagnosed with cancer using an SF3B1 modulator. In certain instances, cancer cells from the patient have been determined to have a mutant SF3B1 protein. Specific SF3B1 mutants include E622D, E622K, E622Q, E622V, Y623C, Y623H, Y623S, R625C, R625G, R625H, R625L, R625P, R625S, N626D, N626H, N626I, N626S, N626Y, H662D, H662L, H662Q, H662R, H662Y, T663I, T663P, K666E, K666M, K666N, K666Q, K666R, K666S, K666T, K700E, V701A, V701F, V701I, I704F, I704N, I704S, I704V, G740E, G740K, G740R, G740V, K741N, K741Q, K741T, G742D, D781E, D781G, or D781N. In certain embodiments, SF3B1 mutants are chosen from K700E, K666N, R625C, G742D, R625H, E622D, H662Q, K666T, K666E, K666R, G740E, Y623C, T663I, K741N, N626Y, T663P, H662R, G740V, D781E, or R625L. In additional embodiments, the cancer cells have been tested to measure the amount of one or more splice variants selected from Table 1. Specific splice variants associated with neomorphic SF3B1 mutations are shown in Table 1 and described in the section on splice variants above.

In certain embodiments, a cancer patient determined to have a mutant SF3B1 protein is treated with an SF3B1 modulator as described in U.S. application Ser. No. 14/710,687, filed May 13, 2015.

EXAMPLES Example 1: SF3B1 Mutations Induce Abnormal Splicing in a Lineage-Specific Manner

To investigate splicing alterations associated with SF3B1 mutations (“SF3B1^(MUT)”) across multiple tumor types, an RNA-Seq quantification and differential splicing pipeline was developed and used to analyze RNA-Seq profiles from the following samples:

all SF3B1^(MUT) samples in The Cancer Genome Atlas (TCGA; from 81 patients in all, representing 16 cancer types), and 40 wild type SF3B1 (SF3B1^(WT)) samples from each of the breast cancer (20) and melanoma (20) cohorts in TCGA,

seven SF3B1^(MUT) and seven SF3B1^(WT) CLL patient samples obtained from the Lymphoma/Myeloma Service in the Division of Hematology/Oncology at the New York Weill Cornell Medical Center.

RNA-Seq Quantification Methods

Splice junctions were quantified directly from alignments (BAM files) to facilitate discovery of unannotated splice variants. For internally generated RNA-Seq data, reads were aligned to the human reference genome hg19 (GRCh37) by MapSplice and quantified by RSEM against the TCGA GAF 2.1 isoform and gene definition, emulating the TCGA “RNASeqV2” pipeline. Splice junction counts generated by MapSplice were used for downstream processing. For TCGA RNA-Seq data, comprehensive splice junction counts generated by MapSplice were not available; instead TCGA “Level 3” splice junction data reports mapped read counts for a predefined set of splice junctions from reference transcriptomes. To reconstruct genome-wide splice junction counts comparable to internally-generated RNA-Seq samples, raw RNA-Seq alignments (BAM files) were obtained from CGHub and any reads that span across a potential splice junction were directly counted. RSEM-estimated gene expression read counts were gathered directly from the TCGA RNA-SeqV2 Level 3 data matrices.

Because MapSplice only provides exon-exon junction counts, estimates of read counts spanning each intron-exon junction were required for identification of intron-retention splice variants. For every splice junction in each BAM file, reads with at least a 3-bp overhang across each of the 3′ and 5′ intron-exon junctions were counted.

For all manipulation of spliced reads within BAM files, a custom Python module “splicedbam” was used, which uses the “pysam” extension of samtools (Li, H., et al., “The Sequence Alignment/Map format and SAMtools.” Bioinformatics, 2009 Aug. 15; 25(16):2078-9).

In some instances, splice junctions had very low counts, occasionally due to sequencing and alignment errors. Therefore, only splice junctions that had at least a total of 10 counts on average from either SF3B1^(WT) or SF3B1^(MUT) cohorts were included in downstream analyses.

Differential Splicing Detection Methods

In order to detect differential usage of a splice variant in one cohort relative to another, independent of gene expression changes and pre-defined alternative splicing models, a computational differential splicing pipeline was developed that converts splice junction counts into percentages of junction usage at splice sites with multiple possible junctions. The percentage of junction usage is a measurement of the occurrence of one splice variant relative to all other splice variants that share the same splice site. For instance, a splice variant with an alternative 3′ splice site must share its 5′ splice site with another splice variant. Therefore, for each shared splice site, the raw counts of each splice variant were divided by the total counts of all splice variants that utilize the shared splice site in order to derive a ratio. This ratio was then multiplied by 100 to convert it to a percentage. For each sample, the sum of all of the percentages of splice variants that share the same splice site will equal 100. The transformation of raw counts of each splice variant into a percentage of all splice variants sharing a splice site is itself a normalization to reduce the effect of gene expression changes. The percentages for canonical and aberrant junctions are listed in Table 1 as “Avg WT %” and “Avg Ab. %,” respectively. Differences between these percentages were assessed for statistical significance by using the moderated t-test defined in the Bioconductor's limma package. The statistical p-values were corrected into q values using the Benjamini-Hochberg procedure, and listed as “FDR Q-Values” in Table 1. Any splice variant that satisfied a q value of less than or equal to 0.05 was considered statistically significant.

The conversion of raw junction counts into percentage junction usage can introduce noise in some instances, i.e., when a gene in which a splice variant occurs is expressed in one cohort but has very low expression or is not expressed at all in another cohort. To address this, an additional filtering step was introduced. For each up-regulated splice variant in an SF3B1^(MUT) sample that satisfies the above q value threshold, its corresponding canonical splice variant must be down-regulated in the SF3B1^(MUT) sample and also must also satisfy the q value threshold for the up-regulated splice variant to be considered an aberrant splice variant.

Identification of Aberrant Splice Variants in Neomorphic SF3B1^(MUT) Patient Samples

Initially, this framework was applied to a subset of known SF3B1^(MUT) cancers or wild-type counterparts from The Cancer Genome Atlas (TCGA; luminal A primary breast cancer: 7 SF3B1^(K700E) and 20 SF3B1^(WT); metastatic melanoma: 4 SF3B1^(MUT); and 20 SF3B1^(WT)) and internally generated 7 SF3B1^(MUT) and 7 SF3B1^(WT) CLL patient samples. This analysis revealed 626 aberrant splice junctions to be significantly upregulated in SF3B1^(MUT) compared to SF3B1^(WT). The vast majority of aberrant splicing events use an alternative 3′ss (see Table 1, “Event” column).

The computational screening of aberrant splicing events revealed a pattern of tumor-specific splicing events in breast cancer, melanoma and CLL in neomorphic SF3B1^(MUT) samples (Table 1). In addition, a set of tumor-non-specific events (i.e., splicing events found in at least two tumor types) was observed. Some splice variants of genes with tumor-specific splicing events occur in genes with higher mRNA expression, indicating that some of the observed tumor-specific splicing results from gene expression differences (FIG. 2 ).

To characterize the effect of aberrant splicing in all SF3B1 variants across cancer types, RNA-Seq data for the remaining 70 SF3B1^(MUT) patients from 14 cancer types in TCGA were quantified, and an unsupervised clustering analysis was done using all 136 samples. This clustering separated splicing events associated with neomorphic SF3B1 mutants from those associated with wild-type SF3B1 or non-neomorphic SF3B1 mutants. For example, splicing patterns associated with neomorphic SF3B1 mutants were observed in breast cancer (SF3B1^(K666E), SF3B1^(2626D)), lung adenocarcinoma (SF3B1^(K741N), SF3B1^(G740V)), and bladder cancer (SF3B1^(R625C)) patient samples, as splicing events in these samples clustered with those in SF3B1^(K700E) neomorphic samples, whereas the splicing profiles for other SF3B1 mutant samples were similar to those of SF3B1′ samples of the same tumor type. A listing of SF3B1 mutants whose splicing profiles clustered with those of neomorphic SF3B1 mutants is provided in Table 3, column 1. Additional SF3B1 mutations that are predicted to be neomorphic are listed in Table 3, column 2. A schematic diagram showing the locations of all mutations provided in Table 3 is shown in FIG. 3 .

TABLE 3 Select SF3B1 mutations SF3B1 Mutations with Splicing Profiles Clustering with Predicted Neomorphic SF3B1 Neomorphic SF3B1 Mutations Mutations K700E K666Q K666N K666M R625C H662D G742D D781G R625H I704F E622D I704N H662Q V701F K666T R625P K666E R625G K666R N626D G740E H662Y Y623C N626S T663I G740R K741N N626I N626Y N626H T663P V701I H662R R625S G740V K741T D781E K741Q R625L I704V I704S E622V Y623S Y623H V701A K666S H662L G740K E622Q E622K D781N

Example 2: Validation of Aberrant Splice Variants in Cell Lines

Aberrant splicing in cell line models was analyzed by collecting RNA-Seq profiles for a panel of cell lines with endogenous SF3B1 neomorphic mutations (pancreatic adenocarcinoma Panc 05.04: SF3B1^(Q699H/K700E) double mutant; metastatic melanoma Colo829: SF3B1^(P718L); and lung cancer NCI-H358: SF3B1^(A745V); obtained from the American Type Culture Collection [ATCC] or RIKEN BioResource Center and cultured as instructed) and from several SF3B1^(WT) cell lines from either the same tumor types (pancreatic adenocarcinoma Panc 10.05, HPAF-II, MIAPaCa-2, Panc04.03, PK-59, lung cancer NCI-H358, NCI-H1792, NCI-H1650, NCI-H1975, NCI H1838) or normal control cells of the same patient (Epstein-Barr virus [EBV]-transformed B lymphoblast colo829BL). RNA-Seq profiles were also collected from isogenic pre B-cell lines (Nalm-6) engineered via AAV-mediated homology to express SF3B1^(K700E) (Nalm-6 SF3B1^(K700E)) or a synonymous mutation (Nalm-6 SF3B1^(K700K)). The isogenic cell lines Nalm-6 SF3B1^(K700E) and Nalm-6 SF3B1^(K700K), generated at Horizon Discovery, were cultured in presence of Geneticin (0.7 mg/ml, Life Technologies) for selection. All RNA-Seq analysis was performed using the same pipeline described for patient samples in Example 1. Unsupervised clustering of cell lines using the aberrant splice junctions identified in patients resulted in clear segregation of Panc 05.04 and Nalm-6 SF3B1^(K700E) from wild-type and other SF3B1-mutant cells.

A NanoString® assay was developed to quantify aberrant and canonical splice variants and was validated using the same cell panel. For the NanoString® assay, 750 ng of purified total RNA was used as template for the nCounter® (NanoString Technologies®) expression assay using a custom panel of NanoString® probes. The sample preparation was set up as recommended (NanoString® Technologies protocol no. C-0003-02) for an overnight hybridization at 65° C. The following day, samples were processed through the automated nCounter® Analysis System Prep Station using the high sensitivity protocol (NanoString® Technologies protocol no. MAN-00029-05) followed by processing through the nCounter® Analysis System Digital Analyzer (protocol no. MAN-00021-01) using 1150 FOVs for detection. Data was downloaded and analyzed for quality control metrics and normalization using the nSolver™ Analysis Software (NanoString Technologies®). The data was first normalized for lane-to-lane variation using the positive assay controls provided by the manufacturer (NanoString® positive controls A-F [containing in vitro transcribed RNA transcripts at concentrations of 128 fM, 32 fM, 8 fM, 2 fM, 0.5 fM, and 0.125 fM, each pre-mixed with NanoString® Reporter CodeSet probes])). Any samples with normalization factors <0.3 and >3 were not considered for further analysis. This was followed by content normalization using the geo-mean of GAPDH, EEF1A1 and RPLP0. All samples were within the recommended 0.1-10 normalization factor range. Each normalized value was then checked to ensure that it was at least two standard deviations higher than the average of background signal recorded for that lane. Any value below that was considered below detection limit. These normalized values were taken for further bioinformatics and statistical analysis.

As observed in the RNA-Seq analysis, only the Panc 05.04 and isogenic Nalm-6 SF3B1^(K700E) cell lines showed clear presence of aberrant splicing (FIG. 4 ).

Analysis of SF3B1 Mutant SF3B1^(Q699H)

The Panc 05.04 cell line carries the neomorphic mutation SF3B1^(K700E) and an additional mutation at position 699 (SF3B1^(Q699H)). To evaluate the functional relevance of this second mutation, SF3B1^(Q699H) and SF3B1^(K700E) mutant SF3B1 proteins were expressed alone or in combination in 293FT cells (FIG. 5 ) for analysis of RNA by NanoString®. To express the mutants in 293FT cells, mammalian expression plasmids were generated using the Gateway technology (Life Technologies). First, the HA-tag mxSF3B1 wild-type (Yokoi, A. et al. “Biological validation that SF3b is a target of the antitumor macrolide pladienolide.” FEBS J. 278:4870-4880 [2011]) was cloned by PCR into the pDONR221, then the mutations were introduced using the site-directed mutagenesis kit (QuikChange II XL, Agilent). LR reaction was performed to clone all the HA-tag mxSF3B1 wild-type and mutants into the pcDNA-DEST40 (Life Technologies). 293FT cells (Life Technologies), cultured according to the manufacturer's instructions, were seeded on 6 wells/plate and transfected with generated plasmid using Fugene (Roche). One μg of DNA per pcDNA-DEST40 HA-mxSF3B1 construct was used for each transient transfection, generated in triplicates. Forty-eight hours after transfection, cells were collected to isolate protein and RNA for western blot and NanoString® analysis, respectively. Protein extracts were prepared by lysing the cells with RIPA (Boston BioProducts). Twenty-three μg of protein was loaded in a SDS-PAGE gel and identified using SF3B1 antibody (a-SAP 155, MBL) and anti-GAPDH (Sigma). Li-Cor donkey-anti-mouse 800CW and Li-Cor donkey-anti-rabbit 800CW were used as secondary antibodies and detected by Odyssey imager (Li-Cor). RNA was isolated from the cells and retrotranscribed using MagMax for Microarray and Superscript VILO II (Life Technologies), respectively, according to the manufacturer manual, and then analyzed with the NanoString® assay.

Expression of SF3B1^(K700E) and SF3B1^(Q699H/K700E) induced aberrant splicing, whereas SF3B1^(Q699H) alone or SF3B1^(A745V) or SF3B1^(R1074H) (a substitution conferring resistance to the spliceosome inhibitor pladienolide B) did not induce aberrant splicing (FIG. 6 ), indicating that SF3B1^(Q999H) is a non-functional substitution.

These data confirm that Panc 05.04 and Nalm-6 SF3B1^(K700E) isogenic cells are representative models to study the functional activity of SF3B1 neomorphic mutations and the activity of splicing inhibitors in vitro and in vivo.

Example 3: Neomorphic SF3B1 Mutations Induce Abnormal mRNA Splicing

The functional activity of neomorphic mutations found in SF3B1^(MUT) cancers was analyzed by expressing SF3B1^(WT), neomorphic SF3B1 mutants, or SF3B1^(K700R) (the mutation observed in a renal clear cell carcinoma patient that clusters with SF3B1^(WT) patients) in 293FT cells and determining splicing aberrations by NanoString®. The expression of all constructs was confirmed by western blot (FIG. 7 ). All SF3B1 neomorphic mutations tested demonstrated the same usage of alternative splice sites observed in patient samples (“MUT isoform” in FIG. 8 ), but SF3B1^(K700R) and SF3B1^(WT) did not show aberrant splicing (FIG. 8 ). Moreover, the expression of none of the SF3B1 constructs changed the overall gene expression (“PAN-gene” in FIG. 8 ) or the canonical splice isoforms (“WT isoform” in FIG. 8 ). This indicated both a correlation between the presence of the neomorphic SF3B1 mutations and alternative splicing as well as similar functional activity of the different neomorphic mutations, as was indicated by the RNA-Seq analysis of patient samples.

The correlation between the SF3B1^(K700E) neomorphic mutation and aberrant splicing was analyzed using tetracycline-inducible shRNA to selectively knockdown the neomorphic SF3B1 mutant or SF3B1^(WT) allele in Panc 05.04 and Panc 10.05 cell lines (neomorphic SF3B1^(MUT) and SF3B1^(WT) cell lines, respectively; obtained from the American Type Culture Collection [ATCC] or from RIKEN BioResource Center and cultured as instructed).

For the knockdown experiment, virus encoding shRNA was prepared in LentiX-293T cells (Clontech), which were cultured according to the manufacturer's instruction. The inducible shRNA were cloned into AgeI and EcoRI of the pLKO-iKD-H1 puro vector. The sequences of hairpins were:

shRNA #13 SF3B1^(PAN) (SEQ ID NO: 1180) GCGAGACACACTGGTATTAAG, shRNA #8 SF3B1^(WT)  (SEQ ID NO: 1181) TGTGGATGAGCAGCAGAAAGT; and shRNA #96 SF3B1^(MUT)  (SEQ ID NO: 1182) GATGAGCAGCATGAAGTTCGG.

Cells were transfected with 2.4 μg of target pLKO-shRNA plasmid, plus 2.4 μg of p Δ8.91 (packaging), and 0.6 μg VSVG (envelope) using TransIT reagent (Mirus). The virus was used to infect Panc 05.04 and Panc 10.05 by spin infection using Polybrene (Millipore). The day after infection, the cells were cultured in selecting media (1.25 μg/ml Puromycin [Life Technologies]) for 7 days to select for shRNA-expressing cells. The selected cells were cultured in the presence or absence of Doxycycline hyclate (100 ng/mL; Sigma) to induce the shRNA. Cells were harvested for protein and RNA at day 4 post-induction. In addition, cells were seeded for colony forming assay and CellTiter-Glo® assay (Promega). At day 9, cells were fixed with formaldehyde and stained with crystal violet.

To confirm SF3B1 knockdown using western blots, protein extracts were prepared by lysing the cells with RIPA (Boston BioProducts). Twenty to 25 μg of protein from each sample was separated by SDS-PAGE and transferred to nitrocellulose membranes (iblot, Life Technologies). Membranes were first blocked with Odyssey Blocking Buffer (Li-Cor) and then incubated with SF3B1 antibody (a-SAP 155, MBL) and anti-GAPDH (Sigma). Li-Cor donkey-anti-mouse 800CW and Li-Cor donkey-anti-rabbit 800CW were used as secondary antibodies and detected by Odyssey imager (Li-Cor).

To confirm SF3B1 knockdown by allele specific qPCR, RNA was isolated from the cells and retrotranscribed using MagMax for Microarray and Superscript VILO II (Life Technologies), respectively according to the manufacturer manual. qPCR was performed using ViiA7 (Life Technologies). The reaction included 20-50 ng cDNA, Power SYBR green master mix (Life Technologies) and 300 nM primers. The following primers were used:

SF3B1^(WT): FW (SEQ ID NO: 1183) 5′-GACTTCCTTCTTTATTGCCCTTC and RW (SEQ ID NO: 1184) 5′-AGCACTGATGGTCCGAACTTTC, SF3B1^(MUT): FW (SEQ ID NO: 1185) 5′-GTGTGCAAAAGCAAGAAGTCC and RW (SEQ ID NO: 1186) 5′-GCACTGATGGTCCGAACTTCA, SF3B1^(PAN): FW (SEQ ID NO: 1187) 5′-GCTTGGCGGTGGGAAAGAGAAATTG and RW (SEQ ID NO: 1188) 5′-AACCAGTCATACCACCCAAAGGTGTTG, β-actin (internal control): FW (SEQ ID NO: 1189) 5′-GGCACCCAGCACAATGAAGATCAAG and RW (SEQ ID NO: 1190) 5′-ACTCGTCATACTCCTGCTTGCTGATC. Biological and technical triplicates were performed.

The western blotting and allele specific PCR both confirmed knockdown of the SF3B1 alleles (FIGS. 9 and 10 ).

To determine the association between the expression of SF3B1 mutations and aberrant splicing, RNA isolated from the cells following doxycycline-induced knockdown was analyzed by NanoString®. In Panc 05.04, after knockdown of the neomorphic SF3B1^(MUT) allele, the aberrant splice variants were downregulated and the canonical splice variants were upregulated, whereas the opposite was observed with selective depletion of the SF3B1^(WT) allele (FIG. 11A), indicating that the neomorphic SF3B1^(MUT) protein does not possess wild-type splicing activity. The expression of a pan shRNA induced the regulation of all splice variants as well as the depletion of SF3B1^(WT) in Panc 10.05 cells (FIG. 11B). SF3B1^(PAN) knockdown impaired growth and colony formation in both cell lines, while a minimal effect was observed with selective depletion of neomorphic SF3B1^(MUT) in Panc05.04 cells (FIGS. 12 and 13 ). When the SF3B1^(WT) allele was knocked down in Panc 05.04 cells, only a partial viability effect was observed, whereas SF3B1^(PAN) knockdown prevented colony formation and cell proliferation (FIGS. 12 and 14 ), indicating that pan-inhibition of SF3B1 leads to antitumor activity in vitro and in vivo.

Example 4: Modulation of Neomorphic SF3B1^(MUT) Splicing

Overall Effect of E7107 on Splicing

E7107 is a small-molecule compound that inhibits splicing by targeting the U2 snRNP-associated complex SF3B (Kotake, Y. et al. “Splicing factor SF3b as a target of the antitumor natural product pladienolide.” Nat Chem Biol 3, 570-575, doi:10.1038/nchembio.2007.16 [2007]). The ability of E7107 to inhibit splicing was observed in an in vitro splicing assay (IVS) using the substrate Ad2 (Pellizzoni, L., Kataoka, N., Charroux, B. & Dreyfuss, G. “A novel function for SMN, the spinal muscular atrophy disease gene product, in pre-mRNA splicing.” Cell 95, 615-624 [1998]) and nuclear extracts from the Nalm-6 isogenic cell lines or 293F cells (Life Technologies; cultured according to the manufacturer's instructions) expressing Flag-tag SF3B1^(WT) or SF3B1^(K700E), as follows.

Nuclear extracts were prepared from 293F cells transfected with pFLAG-CMV-2-SF3B1 plasmids, or from isogenic Nalm-6 cells (SBH Sciences). The plasmids were generated by cloning the mxSF3B1 gene into the HindIII and KpnI sites of pFLAG-CMV2 (Sigma), and the mutations mxSF3B1^(K700E), mxsF3B1^(R1074H) and mxSF3B1^(K700E-R1074H) were introduced using the same site-directed mutagenesis kit. Cell pellets were resuspended in hypotonic buffer (10 mM HEPES pH 7.9, 1.5 mM MgCl₂, 10 mM KCl, 0.2 mM PMSF, and 0.5 mM DTT; for Nalm-6 cells, 40 mM KCl was used). The suspension was brought up to a total of five packed cell volumes (PCV). After centrifugation, the supernatant was discarded, and the cells were brought up to 3 PCV with hypotonic buffer, and incubated on ice for 10 minutes. Cells were lysed using a dounce homogenizer and then centrifuged. The supernatant was discarded, and the pellet was resuspended with ½ packed nuclear volume (PNV) of low salt buffer (20 mM HEPES pH 7.9, 1.5 mM MgCl₂, 20 mM KCl, 0.2 mM EDTA, 25% glycerol, 0.2 mM PMSF, 0.5 mM DTT), followed by ½ PNV of high salt buffer (same as low salt buffer except 1.4M KCl was used). The nuclei were gently mixed for 30 minutes before centrifuging. The supernatant (nuclear extract) was then dialyzed into storage buffer (20 mM HEPES pH 7.9, 100 mM KCl, 0.2 mM EDTA, 20% glycerol, 0.2 mM PMSF, 0.5 mM DTT). Protein concentration was determined using NanoDrop 8000 UV-Vis spectrophotometer (Thermo Scientific).

For in vitro splicing (IVS) reactions, an Ad2-derived sequence (Pellizzoni, L., Kataoka, N., Charroux, B. & Dreyfuss, G. “A novel function for SMN, the spinal muscular atrophy disease gene product, in pre-mRNA splicing.” Cell 95, 615-624 [1998]) was cloned into the pGEM-3Z vector (Promega) using EcoRI and XbaI restriction sites. The resulting pGEM-3Z-Ad2 plasmid was linearized using XbaI, purified, resuspended in TE buffer, and used as a DNA template in the in vitro transcription reaction. The Ad2 pre-mRNA was generated and purified using MEGAScript T7 and MegaClear kits, respectively (Invitrogen). Twenty μL splicing reactions were prepared using 80 μg nuclear extracts, 20 U RNAsin Ribonuclease inhibitor (Promega), 10 ng Ad2 pre-mRNA, and varying concentrations of E7107. After a 15 minute pre-incubation, activation buffer (0.5 mM ATP, 20 mM creatine phosphate, 1.6 mM MgCl₂) was added to initiate splicing, and the reactions were incubated for 90 minutes. RNA was extracted using a modified protocol from a RNeasy 96 Kit (Qiagen). The splicing reactions were quenched in 350 μL Buffer RLT Plus (Qiagen), and 1.5 volume ethanol was added. The mixture was transferred to an RNeasy 96 plate, and the samples were processed as described in the kit protocol. RNA was diluted 1/10 with dH₂O. 10 μL RT-qPCR reactions were prepared using TaqMan RNA-to-C_(T) 1-step kit (Life Technologies), 8.5 μL RNA, and 1 μL of Ad2 mRNA primers/probe set (FW 5′ ACTCTCTTCCGCATCGCTGT (SEQ ID NO: 1191), RW 5′-CCGACGGGTTTCCGATCCAA (SEQ ID NO: 1192) and probe 5′ CTGTTGGGCTCGCGGTTG (SEQ ID NO: 1193)).

To evaluate pSF3B1, in vitro splicing reactions were prepared as described above. To quench the reactions, 6× Laemmli Buffer (Boston Bioproducts) was added, and the samples were subjected to SDS-PAGE gels (Life Technologies). The separated proteins were transferred onto nitrocellulose membranes then blocked with blocking buffer (50% Odyssey Blocking Buffer (Li-Cor Biosciences) and 50% TBST). The blots were incubated with anti-SF3B1 antibody overnight, after several washes in TBST, they were incubated with IRDye 680LT donkey-α-mouse-IgG antibody and visualized using an Odyssey CLx imaging system (Li-Cor Biosciences).

E7107 was able to inhibit splicing in nuclear extracts from both the Nalm-6 cells or the 293F cells expressing Flag-tag SF3B1^(WT) or SF3B1^(K700E) (FIGS. 15A and 15B).

E7107 Binds Both SF3B1^(WT) and SF3B1^(K700E) Proteins

The ability of E7107 to bind both SF3B1^(WT) and SF3B1^(K700E) proteins was evaluated in a competitive binding assay using Flag-tag SF3B1 proteins immunoprecipitated with anti-Flag antibody from transiently transfected 293F cells. Batch immobilization of antibody to beads was prepared by incubating 80 μg of anti-SF3B1 antibody (MBL International) and 24 mg anti-mouse PVT SPA scintillation beads (PerkinElmer) for 30 minutes. After centrifugation, the antibody-bead mixture was resuspended in PBS supplemented with PhosSTOP phosphatase inhibitor cocktail (Roche) and complete ULTRA protease inhibitor cocktail (Roche). Nuclear extracts were prepared by diluting 40 mg into a total volume of 16 mL PBS with phosphatase and protease inhibitors, and the mixture was centrifuged. The supernatant was transferred into a clean tube, and the antibody-bead mixture was added and incubated for two hours. The beads were collected by centrifuging, washed twice with PBS+0.1% Triton X-100, and resuspended with 4.8 mL of PBS. 100 μL binding reactions were prepared using slurry and varying concentrations of E7107. After 15 minutes pre-incubation at room temperature, one nM ³H-probe molecule (described in Kotake, Y. et al. Splicing factor SF3b as a target of the antitumor natural product pladienolide. Nat Chem Biol 3, 570-575, doi:10.1038/nchembio.2007.16 [2007]) was added. The mixture was incubated at room temperature for 15 minutes, and luminescence signals were read using a MicroBeta2 Plate Counter (PerkinElmer).

As shown in FIG. 16A, E7107 was able to competitively inhibit binding of the ³H-probe molecule in a similar manner to either SF3B1^(WT) (IC₅₀: 13 nM) or SF3B1^(K700E) (IC₅₀: 11 nM).

Effect of E7107 and Other Compounds on Normal and Aberrant Splicing

E7107 was also tested in vitro in Nalm-6 isogenic cell lines for the ability to modulate normal and aberrant splicing induced by SF3B1^(WT) and SF3B1^(K700E) protein. Nalm-6 isogenic cells were treated with increasing concentrations of E7107 for six hours and RNA was analyzed by qPCR. As shown in FIG. 16B, canonical splicing was observed, with accumulation of pre-mRNA for EIF4A1 and downregulation of the mature mRNA SLC25A19 observed in both cell lines. Additionally, downregulation of mature mRNA of the two abnormally spliced isoforms of COASY and ZDHHC16 was observed in Nalm-6 SF3B1^(K700E) (FIG. 16B).

To investigate the broader activity of E7107 on normal and aberrant splicing, RNA from Nalm-6 isogenic cells treated for two and six hours at 15 nM was analyzed by NanoString®. Only partial inhibition of splicing was observed at two hours in both isogenic cell lines, and at the level of gene, WT-associated isoforms, and MUT-associated isoform expression. After six hours of treatment, clear inhibition was detected for all isoforms quantified (FIG. 17 ). Similar results were obtained by RNA-Seq analysis of isogenic cell lines treated for six hours with E7107 at 15 nM (FIG. 18 ). Normal and aberrant splicing in the isogenic cell lines was also analyzed by RNA-Seq following treatment with one of additional compounds having formulas 1 or 2. Like E7107, each of these additional compounds inhibited expression of both WT-associated and MUT-associated RNA isoforms (FIG. 19 ; compound is indicated by formula number above each vertical pair of graphs). For the RNA-Seq analysis, cells were washed with PBS after treatment with E7107 or other test compound, and RNA was isolated using PureLink (Life Technology) as reported in the manufacturer's manual. cDNA library preparation, sequencing and raw read filtering was performed as described in Ren, S. et al. “RNA-Seq analysis of prostate cancer in the Chinese population identifies recurrent gene fusions, cancer-associated long noncoding RNAs and aberrant alternative splicings.” Cell Res 22, 806-821, doi:10.1038/cr.2012.30 (2012).

In addition, the ability of E7107 to modulate splicing was tested in mice bearing human tumor xenografts. Nalm-6 isogenic xenograft mice were generated by subcutaneously implanting 10×10⁶ Nalm-6 isogenic cells into the flank of CB17-SCID mice, and tumors from these mice were collected at different timepoints after a single intravenous (IV) dose of E7107 (5 mg/kg) and analyzed to determine compound concentrations and splicing regulation. RNA was isolated from the tumors using RiboPure™ RNA purification kit (Ambion®) and used for NanoString® assay or qPCR. The RNA was retrotranscribed according to the instructions of the SuperScript® VILO™ cDNA synthesis kit (Invitrogen™) and 0.04 μl of cDNA was used for qPCR. qPCR for pre-mRNA EIF4A1 and mature mRNA SLC24A19 and pharmacokinetic evaluation were performed as described in Eskens, F. A. et al. “Phase I pharmacokinetic and pharmacodynamic study of the first-in-class spliceosome inhibitor E7107 in patients with advanced solid tumors.” Clin Cancer Res 19, 6296-6304, doi:10.1158/1078-0432.CCR-13-0485 (2013). The primers and probes used for ZDHHC16 were the following: FW 5′-TCTTGTCTACCTCTGGTTCCT (SEQ ID NO: 1194), RW 5′ CCTTCTTGTTGATGTGCCTTTC (SEQ ID NO: 1195) and probe 5′ FAM CAGTCTTCGCCCCTCTTTTCTTAG (SEQ ID NO: 1196). The primers and probes used for COASY were the following: FW 5′-CGGTGGTGCAAGTGGAA (SEQ ID NO: 1197), RW 5′-GCCTTGGTGTCCTCATTTCT (SEQ ID NO: 1198) and probe 5′-FAM-CTTGAGGTTTCATTTCCCCCTCCC (SEQ ID NO: 1199). E7107 reached similar drug concentrations and modulated canonical splicing (accumulation of pre-mRNA for EIF4A1 and downregulation of the mature mRNA SLC25A19) in both Nalm-6 SF3B1^(K700K) and Nalm-6 SF3B1^(K700E) models and downregulated abnormal splicing of COASY and ZDHHC16 in the Nalm-6 SF3B1^(K700E) cells (FIG. 20 ), as observed in vitro. The canonical and aberrant splice mRNA isoforms were downregulated by E7107 as early as one hour following administration of the compound, and expression normalized shortly after treatment (FIG. 21 ), consistent with E7107 pharmacokinetic profile. Similar results were observed in a Panc 05.04 neomorphic SF3B1 xenograft model (FIG. 22 ). All these data indicate that E7107 is a pan-splicing modulator that can bind and inhibit SF3B1^(WT) and SF3B1^(K700E) proteins in vitro and in vivo.

Example 5: E7107 has Anti-Tumor Activity Via SF3B1 Modulation

SF3B1 modulator E7107 was tested for antitumor activity in vivo by determining the effect of E7107 in a subcutaneous model of Nalm-6 SF3B1^(K700E). 10×10⁶ Nalm-6 SF3B1^(K700E) were subcutaneously implanted into the flank of CB17-SCID mice, and mice were administered E7107 intravenously once a day for 5 consecutive days (QD×5) at three well tolerated dose levels (1.25, 2.5 and 5 mg/kg). After this dosing, the animals were monitored until they reached either of the following endpoints: 1) excessive tumor volume measured three times a week (tumor volume calculated by using the ellipsoid formula: (length×width)/2), or 2) development of any health problem such as paralysis or excessive body weight loss. Partial regression (PR) and complete regression (CR) are defined as 3 consecutive tumor measurements <50% and <30% of starting volume respectively.

In the 1.25 mg/kg group, all animals (n=10) reached complete regression (CR) in the Nalm-6 SF3B1^(K700E) xenograft group. In the 2.5 mg/kg group, 10/10 CRs were observed in the Nalm-6 SF3B1^(K700E) group by day 9. In the 5 mg/kg group all Nalm-6 SF3B1^(K700E) xenograft animals reached CR as early as 9 days post treatment and had mean survival times of over 250 days (FIGS. 23 and 24 ). These data demonstrate antitumor activity of SF3B1 modulator in SF3B1^(K700E) xenografts in vivo.

The ability of E7107 to inhibit splicing in CLL patient samples in vitro was determined by isolating RNA from samples of E7107-treated patient cells treated for 6 hours with E7107 at 10 nM and performing RNA-Seq analysis. To do so, cells were washed with PBS after treatment with E7107, and RNA was isolated using PureLink (Life Technology) as reported in the manufacturer's manual. cDNA library preparation, sequencing and raw read filtering was performed as described in Ren, S. et al. “RNA-Seq analysis of prostate cancer in the Chinese population identifies recurrent gene fusions, cancer-associated long noncoding RNAs and aberrant alternative splicings.” Cell Res 22, 806-821, doi:10.1038/cr.2012.30 (2012). As shown in FIG. 25 , E7107 inhibited the expression of canonical splice isoforms in SF3B1^(WT) and neomorphic SF3B1^(MUT) patient samples. E7107 was able to modulate aberrant splicing in all CLL patient samples carrying neomorphic SF3B1 mutations.

Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims. 

The invention claimed is:
 1. A method of treating a patient having a neoplastic disorder, comprising administering an SF3B1-modulating compound to the patient, wherein a sample from the patient has been tested to determine expression levels of aberrant and canonical splice variants of TMEM14C, and the sample expresses an elevated ratio of aberrant to canonical splice variants of TMEM14C relative to the ratio in a control sample, wherein the aberrant splice variant comprises SEQ ID NO: 95 and wherein the canonical splice variant comprises SEQ ID NO:
 96. 2. The method of claim 1, wherein the sample comprises a blood sample, a bone marrow aspirate, and/or a bone marrow biopsy.
 3. The method of claim 1, wherein the sample from the patient treated with the SF3B1-modulating compound further comprises a neomorphic SF3B1 mutation.
 4. The method of claim 3, wherein the neomorphic SF3B1 mutation comprises a mutation at one or more of positions selected from E622, H662, R625, K666, K700, and V701 in SF3B1.
 5. The method of claim 3, wherein the neomorphic SF3B1 mutation comprises a mutation at one or more of positions selected from H662, R625, and K700 in SF3B1.
 6. The method of claim 3, wherein the neomorphic SF3B1 mutation comprises R625C and/or K700E.
 7. The method of claim 3, wherein the control sample expresses a wild type or non-neomorphic SF3B1 protein.
 8. The method of claim 1, wherein the neoplastic disorder is a myeloid neoplasm.
 9. The method of claim 8, wherein the myeloid neoplasm is myelodysplastic syndrome, acute myeloid leukemia, or chronic myelomonocytic leukemia.
 10. The method of claim 1, wherein the neoplastic disorder is myelodysplastic syndrome.
 11. The method of claim 1, wherein the SF3B1-modulating compound comprises a compound of formula 2:


12. A method of treating a patient having a neoplastic disorder, comprising: a) identifying an elevated ratio of aberrant to canonical splice variants of TMEM14C in a sample from the patient relative to the ratio in a control sample; and b) administering an SF3B1-modulating compound to the patient, wherein the aberrant splice variant comprises SEQ ID NO: 95 and wherein the canonical splice variant comprises SEQ ID NO:
 96. 13. The method of claim 12, wherein identifying an elevated ratio comprises nucleic acid barcoding, real-time polymerase chain reaction (RT-PCR), microarray, nucleic acid sequencing, nanoparticle probes, and/or in situ hybridization.
 14. The method of claim 12, wherein identifying an elevated ratio comprises nucleic acid barcoding.
 15. The method of claim 12, wherein identifying an elevated ratio comprises RT-PCR.
 16. The method of claim 12, wherein the sample comprises a blood sample, a bone marrow aspirate, and/or a bone marrow biopsy.
 17. The method of claim 12, wherein the sample from the patient treated with the SF3B1-modulating compound further comprises a neomorphic SF3B1 mutation.
 18. The method of claim 17, wherein the neomorphic SF3B1 mutation comprises a mutation at one or more of positions selected from E622, H662, R625, K666, K700, and V701 in SF3B1.
 19. The method of claim 17, wherein the neomorphic SF3B1 mutation comprises a mutation at one or more of positions selected from H662, R625, and K700 in SF3B1.
 20. The method of claim 17, wherein the neomorphic SF3B1 mutation comprises R625C and/or K700E.
 21. The method of claim 17, wherein the control sample expresses a wild type or non-neomorphic SF3B1 protein.
 22. The method of claim 12, wherein the neoplastic disorder is a myeloid neoplasm.
 23. The method of claim 22, wherein the myeloid neoplasm is myelodysplastic syndrome, acute myeloid leukemia, or chronic myelomonocytic leukemia.
 24. The method of claim 12, wherein the neoplastic disorder is myelodysplastic syndrome.
 25. The method of claim 12, wherein the SF3B1-modulating compound comprises a compound of formula 2: 